I IN:
l. M. Bohr J. J . ReDrard
CENTER fOR WETlAND RESOURCES LOUISIANA Sf ATE UNIVERSITY
I LA. 70803
Sea Grant Publication No. LSU-T-76-00S
This work is a result 01 research sponsored by the National Oceanic and Atmospheric Administration, U.S. Dept. Commerce, through the Office of Coastal Zone Management and the Office of Sea Grant.
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I
contents
List of Figures, List of Tables • Acknowledgments, Abstract .. Introduction , , Definitions. . . Overview of Ecological Function of
the Ecosystem. . • . . . . • . Effects of the Hydrologic Regime on
the Ecosystem, . . , , , . . . . Effects of Geological Processes on
Biological Functioning of the Ecosystem. . , . . . . . , . • . • . • •
Swamp Forest and Associated Water Bodies Swamp Forest Wetland Proper .. , •.
Autotrophs and Primary Production, • Primary Production and
Primary Consumption . . . . • . . • Swamp Forest Associated Water Bodies
Primary Production . Primary Consumption ••••.• Predation .•••.••.•••
Organisms of Special Interest or nomic Significance to Man •
Fresh Marsh and Associated Water Bodies •• Fresh Marsh Wetland Proper • • • • •
Autotrophs and Primary Production. Primary Consumers. • ••• Detritivores • . • . • . • • • Carnivores . . . . . . ... . .
Fresh Marsh Associated Water Bodies •• Primary Production and Organic
Input from Wetland. Primary Consumers. Carnivores ......... .
Organisms of Special Interest or Economic Significance to Man.
Brackish Marsh and Estuaries • • • • • Brackish Marsh Wetland Proper •.
Autotrophs and Primary Production. Primary Consumers. Detritivores . • • • . . • . . • • Carnivores . • • . . • • . . . . .
Brackish Marsh Associated Water Bodies Primary Production Primary Consumers. Carnivores .
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viii 1 1 4
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13 15 16 17
18 21 22 23 23
24 26 26 27 30 31. 31 32
33 34 35
36 37 38 39 40 41 43 43 43 44 45
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Organisms of Special Interest or Economic Significance to Man ..
Salt Marsh and Associated Estuaries. Salt Marsh Wetland Proper.
Primary Production . Primary Consumers ..• Carnivores • . • . . • •
Water Bodies (Estuaries) Primary Production . • . Primary Consumption •. Predation in Salt Marsh Estuaries .•
Organisms of Special Interest or Economic Significance to Man .•
Offshore Areas . . • . • • Primary Production • Primary Consumption. Carnivores . . • • .
Organisms of Special Interest or Economic Significance to Man.
Beaches ....••.. Beach Vegetation . .
Elevated Coastal Areas . Vegetation Succession on Spoil Banks
Saline Marsh . Brackish Marsh . Fresh Marsh. Swamp ..•... Overview ..•
Survey of Selected Coastal Organisms Invertebrate Example (Blue Crab) Fish. ,. ." .. Amphibians and Reptiles. Birds ... Mammals ..
Literature Cited , Appendix: Louisiana's Refuges, Wildlife
Management Areas, and Game Preserves,
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u s
The major environmental units of Barataria Basin . . . Model of the Blue crab sub habitats in the Barataria estuary • . . . Crab landings from the Barataria estuary. 1959 to 1970 . . . . ,
46 i 48J ~'9~~ 49 51 53 54 54 55 56
57 60 62 62 65
66 67 67 70 73
;{) 74 75 76 78 78 80 85 89
119 129
133
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List of Tables
Table 1
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3
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5
6
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Percentage of tree in Cypress~tupelo gum swamp and bottomland hardwood forest of the Barataria Basin Percentage of plant species in fresh marsh portions of Barataria Basin . . . . . . Percentage of aquatic plant species in freshwater habitats for the Louisiana coastal zone in general . . . . . . . . . . Percentage of plant species in brackish marsh areas of Barataria Basin . . . . . . Percentage of aquatic plant species in brackish water habitats for the Louisiana coastal zone in general Percentage of plant species in the salt marsh region of Barataria Basin . . . . . . . Plant species composition of spoil banks and natural levees in coastal Louisiana . . . . Plant species composition of large crevasses and natural levees in the Louisiana deltaic plain • . . • . • . . . . . . • Tree species composition of cheniers in coastal Louisiana Fish species collected in the four major habitat types in the Louisiana Offshore Oil Port Study (LOOP Report) . • Percentage alligator populations according to marsh zone and marsh types • . . • . .
Reptiles known or likely to occur in Barataria Basin (all habitats) . . . . • Amphibians known or likely to occur in Barataria Basin (all. habitats) . . . . . . A list of 216 species of birds identified in all habitats of Barataria Basin
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33
40
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50
71
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72
81
87
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90
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Table 15
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Seasonal occurrence of fishing birds along beach area of Bay Champagne • . . . Seasonal occurrence of shore birds along beach area of Bay Champagne . . . . Peak number of individual wading birds/lOa acres observed August 1973-July 1974 with a mean value for the year in the fresh marsh areas of Barataria Basin ..••........ Peak number of individual wading birds/lOa acres observed August 1973-July 1974 with a mean value for the year in the brackish marsh area along Bayou Lafourche Peak number of individual wading birds/lOa acres observed August 1973-July 1974 with a mean value for the year in the salt marsh area along Bayou Lafourche . . . Peak number of individual wading birds/lOa acres observed August 1973-July 1974 with a mean value for the year in an impounded area north of the mouth of Bayou Lafourche . . , . . . . . . Wading birds/lOO acres in the marsh environments of southeast Louisiana along a 400~m wide transect . . . . . . . . . . . . Bird rookeries and their popu~ lations in Barataria Bay system Puddle ducks/lOa acres in the marsh environments of southeast Louisiana along a 400-m wide transect . . . . . . . . . , . . IvIean and peak numbers of puddle ducks seen in each marsh and total (mean and peak) numbers of puddle ducks seen for all marsh types . . . . . . . . . . .
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97
100
100
101
101
102
103
106
107
Table 25 Peak number of individual -water~
fo-wl species/lOO acres observed 1973~July 1974 -with a mean
value for the year in fresh marsh
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areas in Barataria Basin .. " ..•. 107 26 Peak number of individual -water~
fo-wl species/lOO acres observed August 1973-July 197Lf -with a mean value for the year in brackish marsh areas in Barataria Basin. .,.. 108
27 Peak number of individual -water-fo-wl species/lOa acres observed August 1973-July 1974 -with a mean value for the year in salt marsh areas in Barataria Basin . . .. .... 108
28 Peak number of individual water-fowl species/lOa acres observed August 1973-July 1974 with a mean value for the year in an impounded area north of the mouth of Bayou Lafourche . . . . . . • • • . • • • . . . 109
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Diving ducks/lOa acres in the marsh environments of southeast Louisiana along a 400-m wide transect . . • • . . . • . • • . Mean and peak numbers of diving ducks seen in each marsh type and total (mean and peak) numbers of diving ducks seen for all marsh
...• 111
types . . CI • • • • • • •• ••••• III
31 Coots (Fulica americana)/lOO acres in the marsh environments of southeast Louisiana along a400-m transect . . • . • . . . . . .. ..•• 112
32 Mean and Peak numbers of coot (Fulic~ ~mericana) seen in each marsh type and total (mean and peak) numbers of coots seen for all marsh types • . . . . . . . . . • • . 112
33 September waterfowl populations (in thousands) for southeastern Louisiana (Atchafalaya Bay-Lake Borgne). . . . . . . . . . . • • . . • • • 113
34 October waterfowl populations (in thousands) for southeastern Louisiana (Atchafalaya Bay-Lake
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Table 35
36
37
38
39
40
L}l
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November waterfowl populations (in thousands) for southeastern Louisiana (Atchafalaya Bay-Lake Borgne) ........... . December waterfowl populations (in thousands) for southeastern Louisiana (Atchafalaya Bay-Lake Borgne) · · · · · · · · · · January waterfowl populations (in thousands) for southeastern Louisiana (Atchafalaya Bay-Lake Borgne) · · · · · · · · · · · · February waterfowl populations (in thousands) for southeastern Louisiana (Atchafalaya Bay-Lake Borgne) · · · · · · · · ·
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Migrant species of birds observed 21 March-lO May 1972 in the Caminada Chenier (total area, 4,000-m) · · · · · · · Density of muskrat houses in Barataria Basin . · · · · · · Harvest values for fur animal in Louisiana during the 1971-72 and 1972-73 seasons · · · · Potential carrying capacity and present population estimates of deer, squirrel, and rabbit of the marsh and swamp areas of Barataria Basin . · · · · · · · · Mammals that may occur in the various environmental units of Barataria Basin . · · ·
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This work is a result of research
. · ·
. · ·
· ·
by the National Oceanic and Atmospheric Adminis~
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tration. U.S. of Commerce. the Office of Coastal Zone and the Office of Sea Grant. The activity is coordinated through the Louisiana State Planning Office.
The nature of this study required assistance and information from a relatively large number of individuals and agencies. Work primarily involved collection, analysis. and interpretation of existing
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data located at a number of sources. The authors are particularly indebted to the individuals, departments. and agencies listed belo"J:
The Study Team of the Louisiana Coastal Zone Hanagement Program Patrick RyAn, Director, State Planning Office; Lyle St. Amant, Assistant Director, Louisiana Wildlife and Fisheries Commission; and Jack R. Van Lopik, Director, Louisiana Sea Grant Program.
Louisiana State University, Baton Rouge Campus: George Lowery, Boyd Professor, Zoology, and Director, Huseum of Natural Science; Leslie L. Glasgow, Professor and Assistant Director, School of Forestry and Wildlife Management; Robert Chabreck, Associate Professor, Forestry and Wildlife Management; A. W. Palmisano, Assistant Leader, Louisiana Cooperative Wildlife Research Unit; L. W. DeLabretonne, Jr., Specialist, Cooperative Extension Service.
Louisiana State Planning Office: Patrick W. Ryan, Director; Paul R. Hayer, Jr., Assistant Director; Coastal Resources Program: Paul H. Templet, Program Coordinator; Lynne Hair, Assistant Program Coordinator; John M. Bordelon, Chief Planner; Jim Renner, Economic Planner.
United States Army Corps of Engineers, New Orleans District: Frederick M. Chatry, Charles W. Decker, and James F. Roy, Supervisory Civil Engineers; Billy J. Garrett and Alfred P. Becknel, Supervisory Hydraulic Engineers; Joan F. Bergen, Civil Engineering Technician; Charles Grimwood, Hydraulic Engineer; Roy Leslie Farmer, Civil Engineer; and Wm. E. Shell, Supervisory Environmental Resources Specialist.
Louisiana Wildlife and Fisheries Commission: Barney Barrett, Geologist; Hugh Bateman, Waterfowl Biologist; Greg Linscombe, Research Biologist; Harry E. Shafer, Jr., Chief, Oysters, Water Bottoms, and Seafoods Division; and Max W. Summers, Assistant Chief, Oysters, Water Bottoms, and Seafoods Division.
U.S. Department of the Interior, Bureau of Sports Fisheries and Wildlife: S. Ray Aycock, Jr., Wildlife Biologist.
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91)°30' 90°00' 89°30'
30°00'
29°30'
15 20 25 30 Km. 1M
Fig. 1. egetation habitats of Barataria Basin.
Abstract
Introduct ion
The biological characterization of the Barataria Basin includes a functional description of biological processes at both the ecosystem (basin) level and the habitat level, as well as summaries of research on distribution and abundance of Animal groups 0
Water represents the prime integrating feature of the total ecosystem. The importance of rainfall, tidal flow, wind, temperature, storms, meandering of streams, and discharge from the Mississippi River is emphasized in relation to distributions of organisms and nutrients and also as a vehicle for pollutants.
On the habitat level, swamp forests, fresh marshes, brackish marshes (including the inter~ mediate marsh), saline marshes, beaches, and other elevated areas (i.. e., chenieres, natural levees, and spoil banks) are discussed in terms of probable energy pathways by classification of organisms as producers, primary consumers (herbivores and detritivores), or secondary consumers (carnivores), with emphasis on water and its relationship to nutrient transport.
This volume presents a description of the biological function of the wetlands, water bodies, and offshore areas of the Barataria Basin. This broad, low-lying region, representing the most recently abandoned Mississippi River delta complex and its adjacent estuarine and offshore waters, is characterized by a set of ecological parameters that are integrated into a complex, dynamic ecosystem of enormous biological productivity. To describe this system is the goal of this report, and the description must include interactions among components as well as an inventory of those components. The biological function of the basin is closely tied to physical and chemical processes; therefore these processes will be considered in terms of their effects on biological activity.
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The Barataria Basin system can be divided into five primary environmental units and two secondary units (Fig. 1). Swamp forest, fresh marsh, brackish marsh, saline marsh, and the offshore area are the primary units. For the purposes of this discussion, intermediate marsh (sometimes considered an intermediate stage between fresh and brackish marsh) has been included with brackish marsh. These primary units are treated in order of increasing salinity regimes since net water flow occurs in this direction, and water is considered the major integrative element of the system. Beaches and other elevated areas (cheniers, natural levees, and spoil banks) are the two secondary units. Each of these basic environmental units is shown in Figure 1.
A brief general discussion of the total Barataria Basin is presented first, followed by a detailed description of each environmental unit. The latter accounts deal both with the general biological function of the environmental unit and with the distribution and abundance of various species and biotic groups in the environmental unit. Details on biological function have been derived from a combination of knowledge of the system itself and published information from other similar ecosystems and represent current thinking on principles that have long been recognized by f'eoloeistso Each of the primary units is treated in terms of wetland proper (land that is alternately flooded and drained) and associated water bodies (all permanently inundated areas such as lakes, bayous, and estuaries).
Along with the functional description of a given unit is an inventory of organisms inhabiting it, including a characterization of the vegetation and an account of major vertebrate groups. Since the bulk of biological research in coastal Louisiana is still at the level of reconnaissance, knowledge of many groups of organisms is restricted to a simple list of what species are present. For other groups, some index of abundance is available, which may bea one-time estimate or may show seasonal or annual variations in numbers. Only a few species of plants have been studied in enough detail to fit into a rigorous energy flow scheme, and few animal populations have been examined to this degree, e.g., many functionally
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important but commercially worthless organisms remain to be examined.
Because many vertebrate cross over into several environmental units, and because of lack of hab data for many mammals birds and amphibians and reptiles are treated in individual sections for the entire basin~ Oysters, shrimp, and menhaden, because of their great economic importance and the special problems associated with working from harvest data, are also discussed in detail in separately published reports. In an additional report the principles of chemical nutrient cycling that prevail in the Barataria Basin are addressed, as these principles are extremely important to the biological activity in the region.
It should be stated here that the Barataria Basin is extremely dynamic and, like other sections of the Louisiana coastal area, is undergoing constant change owing to geologic and human processes. The Barataria Basin is a part of the geologically active Mississippi River deltaic plain, in an area that is subsiding and eroding. As man's activities in the area have increased, the already dynamic nature of the system has been magnified, and physical and biological changes are occurring at an ever-increasing rate.
One well-documented example of such change is the northward movement of oyster grounds in the Barataria Basin over the last several decades, which is presented in the section on oysters. The sessile nature of the oyster makes it an ideal indicator of the effects of changes in the physical environment on the habitats and distribution of some estuarine organisms. Motile forms, such as trout and menhaden, are more difficult to sample quantitatively, and the effects of habitat change on their distribution are less well known~
Because of the value and fragility of the enormous biological productivity in the Barataria Basin, planners must pay close attention to environmental changes and their causes and effects. To do this, a basic understanding of the biological function of the Barataria Basin ecosystem is essential. In the fishing discussion, unreferenced data are taken from Gosselink et a1. (1976).
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Several ecological terms that will be used throughout this discussion are defined as follows:
Primary production: The production of organic carbon through photosynthesis, the photochemical process by which oxidized carbon (carbon dioxide) in the atmosphere is reduced to organic carbon thereby converting solar energy to potential chemical energy. This process requires a biochemical catalyst (chlorophyll) and water as well as sunlight and inorganic nutrients and yields atmospheric oxygen as a by-product. It is the basis for all biological production.
Primary productivity: The rate at which autotrophs (see below) manufacture organic carbon, expressed as grams carbon or organic matter produced per unit area per unit time. Variation in primary productivity between different plants (and different ecosystems) makes this parameter extremely useful as an index of comparison.
Autotroph: Any organism capable of primary production. Autotrophs make up the first trophic level, or level of energy conversion, on which all other trophic levels are ultimately dependent. All green plants are autotrophic. A common synonym for autotroph is "producer."
Heterotroph: Any organism that cannot thesize and thus requires organic carbon, either directly or via another heterotroph. A member of any trophic level above the autrophic level. A common synonym for heterotroph is "consumer."
Herbivore,: A primary consumer or member of the second trophic level that feeds on living plant material, e.g., muskrat, aphid.
Detritivore: A member of the second trophic level that feeds on dead organic material, e.g., crawfish, hacteriao
A hetero or parasite), e.g., channel bass, Louisiana heron.
DE!~},-i~us: Nonliving organic matter (predominantly of plant origin). Most plant material in the coastal zone ultimately ends up as detritus.
Respiration: The complete metabolic oxidation by living organisms of organic material. This
± tb
process makes the energy of organic compounds available to an organism to do ,york. Respir~
ation uses oxygen as well as reduced carbon and is equivalent to the opposite of primary
since the energy fixed photosynthesis is released during respiration.
~ZJL_~low: The transfer of energy from one trophic level to another via ingestion, or to the environment via respiration or egestion.
Standing stock or standing biomass: The density of a particular organism or group of functionally related organisms (e.g •• autotrophs) at any given time or averaged over any given period of time, usually given as grams dry weight or grams carbon per unit area.
Eutrophic:. The term used to describe the "unhealthy" state of an aquatic environment, such as a lake or bayou, in which organic matter (especially autotrophs) and inorganic nutrients are too highly concentrated. Eutrophic areas are generally low in dissolved oxygen, especially at night when photosynthesis ceases.
Heterotrophic system: A community of organisms in which total respiration exceeds total production, i.e., local primary production is insufficient to support energy requirements and energy is imported from another area.
Species diversity: A measure of the relationship between numbers of different species and the total number of all organisms in an area. Several mathematical diversity indice.s are used in ecological studies, but in this report, the term is used in a qualitative sense only and refers to the number of different species found in a particular area. Species diversity is an index of stability in ecological systems, high stability being· correlated with high diversity.
Natural selection: A process of elimination of organisms poorly adapted to their environment and survival of well-adapted individuals. Bett~r-adapted individuals are most likely to reproduce and pass on their adaptive traits to their offspring.
Competition: A process by which two or more organisms or groups of organisms, of the same or different species, utilize the same resource (e.g., food) that is in limited supply.
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This can result in both long-term (evolution-· ary) and short-term (behavioral) adjustments that alleviate the competition.
Several groups of organisms often referred to in the discussions of environmental units are based not on trophic relations but rather on life "style" or habitat.. These groups are defined below:
Nekton: Large, actively swimming aquatic animals, both vertebrates and invertebrates, e.g., shrimp, finfish.
Phytoplankton: Nonvascular plants that grow suspended in water, primarily single-celled algae.
Zooplankton: Small aquatic animals that spend their life suspended in the water column, e.g., copepods, rotifers, and other small crustacea.
Macrobenthos: The community of larger animals that spend their adult lifetimes living on or in the sediments of aquatic systems. Generally, the sessile or relatively nonmotile forms, such as bivalves, are considered part of the benthic community, while decapods, such as shrimp and blue crabs, which are sometimes buried and sometimes swimming, are considered nekton.
Meiofauna: A somewhat ambiguous group of very animals that are generally found in
bottom sediments of aquatic systems. Nematodes comprise a major portion of total meiofauna. Although these organisms are very small, they are also very numerous, and often they are extremely important to the functioning of an ecosystem. They may, for example, play important roles in nutrient cycling.
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Overview of Ecological Function i of m
The following brief description of some of the more obvious features of the Barataria Basin ecosystem of southeastern Louisiana includes division of the total system into five primary environmental units and two secondary units. At this time some general ecological principles are
to demonstrate that the primary units are all interacting components of a coherent ecosystem, and that each possesses analogous features and functions.
A number of factors--the Mississippi River, the climate, and a set of biotic and physical gradients--have interacted to create the specialized and highly productive Louisiana coastal ecosystem, of which the Barataria Basin is a key component. The entire coastal region of the state, including Barataria Basin, is probably the most productive natural area in the United States and is among the most productive in the world. The Louisiana coastal zone supports the nation's largest commercial fishery. with the Barataria Basin during the period 1963-67 producing 30 percent of the state's blue crab harvest, 27 percent of the shrimp harvest, and 47 percent of the menhaden harvest. The basin also provides its share of Louisiana's fur harvest, which is also the largest in the nation. The basin sits at the terminus of the Mississippi flyway--the largest waterfowl migratory route in North America--and provides for millions of user-days of recreational activity. The Lac des Allemands swamps, at the headwaters of the basin, during the early decades of this century housed the world's largest cypress lumber industry, and the massive petroleum productivity of the basin is proof of the areas's biological productivity in past geologic times. In all, this tremendous biological productivity is immensely valuable and deserves to be understood and maintained.
Water is considered the prime integrating feature of the entire ecosystem, as will be discussed below. First, some background information is necessary. Ecosystems are not random associations of independent organisms. Rather, an ecosystem comprises an integrated set of interdependent biological components that are preadapted to the local set of physical conditions in such a way that all basic functions
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can be carried out. Ecosystems go through stages of development (succession) following major physical disturbances. After maturation, an undisturbed ecosystem remains at a dynamic steady state, during which energy and matter coming into the system are balanced by losses from the system. Individual biological components are prevented from large fluctuations by control mechanisms developing simultaneously with maturation of the system. For example, competition for resources among populations of organisms and the process of natural selection together often lead to the development of feedback loops, preventing the domination of anyone group. In other words, those resources that are in shortest supply control or limit the biological processes dependent on them. This control then becomes the basis for a biological cycle. For example, the addition of fertilizer to a pond or marsh area results in a temporary increase in primary production, but as the additional nutrients are incorporated into plant tissue, primary production slows down again. After depletion of existing stores of nutrients, subsequent production becomes dependent on the death and decomposition of living plants. Cycles of matter through an ecosystem are thus keyed to the generation time of individual populations. For example, the turnover rate of organic matter in the swamp forest is much slower than in the salt marsh. because the standing biomass (trees) in the former system is much greater and the generation time of trees much longer than that of oyster grass, A slow turnover rate indicates that a system would take longer to recover from a disturbance.
Large-scale cycles are also triggered by annual physical variations in light and temperature. These variations are most striking in
laLlLmlet:i, e. g" Lhe zone where ion shuts dmvTI almost
during the winter, resulting in dramatic annual of ion and consumption. In the
Barataria Basin, which borders on a subtropical latitude, there is considerable overlap between production peaks of plants, and seasonal variation in production is less marked, although there is still a marked seasonal pulse of production.
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Matter is recycled through ecosystems, but energy flows continuously through the system. Solar energy, the source of all biological energy. is captured in biological compounds by photo-
is and then released to do work through oxidative processes such as All energy is eventually degraded into which is released into the environment and is no longer available for work. At each tropic stage (primary production, ingestion by primary consumers, predation by carnivores, and death and decomposition of organisms) a large portion of the original energy is lost, and organic carbon is converted to carbon dioxide. Thus a large reduction in biomass production must occur at successively higher trophic levels. For example, predators require on an annual basis an amount of food in the form of prey organisms equivalent to perhaps ten times their own (predator) biomass. The relatively small predator biomass is crucial to the overall system, however, because predators act to regulate herbivores, and this feedback loop ultimately helps to prevent overgrazing by herbivores.
Ecosystems are organized around the first trophtc level (autotrophs) on which the capture of solar energy depends. Wetland, marine, and freshwater ecosystems are thus organized around hydrophytes (plants requiring either total or frequent inundation).
Water is required by all living organisms but extreme differences in water requirements have, over millions of years, led to the separation of groups of organisms into systems with similar needs and tolerances.
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Water not only supplies physiological requirements of living organisms; it also does work in an ecosystem in the form of transportaint material (Living and nonliving). The coastal ecosystem is regulated directly by water flow, and connections between the various subunits are mediated strictly by their intersecting network of waterbodies, which serve as conduits of matter and information.
The effect of water movement is illustrated by the edge effect, which is a major factor in the function of each primary environmental subunit. The edge or interface principle, briefly stated, indicates that biological (and chemical) activity is most pronounced at the boundary between a terrestrial and an aquatic system. In this sense an estuarine system is a giant interface. Marsh estuaries are considered to be among the most productive of all natural ecosystems.
Close examination of the present study area shows it to be composed of a multitude of edges or boundaries between water and wetland, and there is an apparent trend of increasing boundary surface from swamp forest to salt marsh.
Primary production in wetlands has long been known to be related to proximity to waterbodies Streamside marsh is always more lush than corresponding inland areas. Animal populations are also especially dense and diverse along the streamside. One reason for increased animal diversity at marsh-water interfaces is the fact that both terrestrial and aquatic forms can inhabit the interface zone, and enhanced prey density attracts more predators.
Augmented primary production in streamside areas is thought to be related to water movements, vertical and horizontal. Input of nutrients and flushing away of waste products are two key factors. Optimum productivity occurs between the extremes of excessive water movement such as is shown on a high energy beach, and stagnation, which often results from disturbance of normal circulation.
The normal ircul.ation terns across the Barataria Basin are therefore key elements in the functioning of this coastal ecosystem. The biological community found at any location \.,ithin the system, for instance, is to a major degree a function of the hydrologic regime (the patterns and magnitudes of all water movements) at that point.
Another physical factor regulating the of the coastal ecosystem is
water , which is also controlled by the hydrologic
stress that is felt at the southern (Gulf) end of the basin and that is almost in the swamp forest~ The primary cause of the gradual decrease in plant diversity as we move seaward in the basin is believed to result from the increased ability of the few salt~tolerant species to dominate the more saline areas. Thus the species composition and function of the southerly end of the basin is controlled more by physicochemical parameters, w'hile the highly diverse swamp forest is regu~ lated more by intense biological competition among a variety of plants and animals,
An additional hydrographic aspect related to ecosystem functioning is the degree to which small waterbodies (bayous and creeks) meander. The tortuous meanders of natural bayous and tidal creeks are extremely important because they maximize interface area, also preventing rapid drainage of the system. Straight canals, such as are inevitably the product of man's "efficiency," not only decrease the water level in an area by augmenting flow rates, they often disrupt a natural drainage network and block normal circulation. For example, a man-made canal dredged across a natural stream will, by blocking and reducing normal flows, alter the downstream portion of the natural waterbody in a different manner than would a parallel canal that would increase flow rates (McHugh and Stone, unpublished data). Also, dredged canals often speed up salinity intrusion, which gradually turns brackish areas to saline areas.
Finally, the Mississippi River is a dominant feature of the hydrologic regime of the marine waters offshore from the Barataria estuaries and also those inshore. Surface salinities in Barataria Bay are partially dependent on Mississippi River discharge. The waters of the Mississippi River also strongly modify salinities in the offshore area, especially in surface waters. This fresh water is nutrient rich, high in nitrates as
with "laters that are atmnonia~rich, Primary production is influenced
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by these fresh waters~ as is planktonic species composition.
In terms of man-produced impacts on the biological function of the Barataria system, the hydrologic pattern in the basin is of great importance because it serves as a means for the introduction and distribution of pollutants. A tremendous amount and incredible variety of industrial a.nd domestic wastes are introduced via the Mississippi River and other waterways. These include heavy metals, pesticides, domestic sewage, and many others. In some cases these pollutants actually directly affect biological productivity of certain functionally or economically important species groups, and in other cases productivity is indirectly affected because species are rendered unfit for human consumption or use.
Just as hydrologic processes affect biological activity, biological processes also exert important forces on hydrologic regime, especially through the formation of wetlands. The major portion of marshland soils in coastal Louisiana is organic matter in the form of peat. This results from the continual production of marsh grass, some of which becomes buried and remains unoxidized. In general, the accumulation of peat and waterborne sediment trapped by marsh plants keeps up with the rate of coastal subsidence (sinking), and marshland maintains a "steady state" balance with sea level. If the marsh grasses are disturbed and their productivity decreased, however, the wetland rapidly sinks below sea level and becomes open water, which is considerably less productive.
Additionally, wetland is extremely valuable as a buffer to storm surges--even a narrow bank of marshland can reduce large waves to minor ones.
An in-depth description of the hydrologic and processes of the Barataria Basin is separatelv published in this series.
Effects of Geological on al Funct
Although the coastal hydrologic regime integrates a set of biological processes and thus controls community • this is itself a function of the long-term geological processes of sediment accretion and erosion and coastal subsidence All eeoerRphicRl chRrR~ter
istics of the coastal area are basically the result of the Mississippi River ",ith its histor-ical switching behavior and massive sediment input. Descriptions of the geological history and processes of the Barataria Basin are separately published in this series.
When the river shifts into a new channel, land is built rapidly. Many minor distributaries serve to spread the water and sediment over fairly broad areas. Erosion takes place continuously, but the new delta is dominated by the river during the building stage of the cycle. The total length of land-water interface is relatively short during this stage.
As the river begins to seek a new channel and discharges more and more water through major distributary channels, erosion becomes increasingly more important in the delta area. (This process extends over a period of several hundred years.) As more land is lost, the interface length becomes longer owing to formation of small bays, ponds, and meandering tidal channels. Since total biotic productivity is a function of both interface length (related to the "edge effect") and total marsh area, total productivity for anyone bay system reaches a maximum during the erosion cycle after inorganic sediment input diminishes. After this point is reached, however, the productivity losses owing to increasing erosion of marshland are greater than the productivity gains acquired by increasing interface length; therefore, total productivity begins to decrease.
Thus there seems to be juvenile, mature, and senescent stages of interdistributary bay systems. Land area is maximum in the juvenile stage and then decreases in the other two stages. The length of the land-water interface is low during the juvenile stage, increases to a maximum during the mature stage, and then decreases in the senescent stage. Productivity seems to be highest in the mature stage. Because the river has continually channels in the there
13
1L1
have always been fresh juvenile estuaries waiting in the wings. It's similar to a relay race with fresh new runners waiting as the fatigued runner finishes his lap.
Today, however, this natural cycle of deltaic development is no longer operative. Because of artificial leveeing, the river is kept in its present channel and overbank flooding is elimin-ated. The present delta of the river has built up to the edge of the continental shelf and most of the river's sediment load is being emptied into deep Gulf waters where it is of no use in land-building processes. Yet, despite the fact that natural land-building processes have been all but eliminated, the natural erosion processes continue, with loss of wetland area augmented by activities such as dredging, leveeing, and drainage and reclamation. This biological activity in the Barataria Basin is threatened by the natural erosion process of interdistributary bay systems and by the augmentation of this process by human activities.
For st and ies
at
A swamp is defined as a woody community in an area where the soil is usually
saturated or covered \vith water for one or more months of the growing season. The swamp community is affected water level and For • cypress and are characteristic of the more poorly dra.ined area.s, and dense hardwood stands are found in slightly more eleva~ ted, better drained areas. A few centimeters of elevation in the swamp has been said to be more critical to the plant community than hundreds of meters in mountainous country.
The following discussion is based on information gained from the des Allemands swamp forest, the upper freshwater basin of the Barataria watershed. The area is funnel-shaped, beginning at the edge of elevated natural levee areas at the intersection of the Mississippi River and Bayou Lafourche and widening to the southeast between these two levee ridges. The swamp forest habitat merges with fresh marsh in the areas surrounding and south of Lac des Allemands and Lake Boeuf (see Fig. 1). Other small areas of swamp forest lie further seaward along the fringes of the natural levee systems of Bayou Lafourche and the Mississippi River.
In the Barataria drainage system, 242,048 acres of swamp forest comprise approximately 21 percent of the wetland of the basin. The ratio of wetland area to waterbody area is highest here and decreases in a seaward direction as waterbodies become more dominant.
Swamp forest is markedly different from other Louisiana wetland by virtue of its characteristic dense stands of woody vegetation dominated by bald cypress, tupelo gum, and drummond red maple. The swamp forest abounds with aesthetic beauty, related both to its complexity and color and to the profound impression gained by even a casual observer that such ecological processes as predation and competition for space are especially intense and dynamic here.
Maximum species diversity of the swamp forest plant community occurs at the environmental interface between wetland proper and water bodies. The wetland is described first, followed by a discussion of waterbodies within the swamp forest unit.
15
16
Swamp Forest Wetland Proper
The boundary between swamp forest and fresh marsh in southeastern Louisiana corresponds approximately with the function of two major soil types, recent Mississippi alluvial soil occupied by swamp forest, and coastal marsh soils on which all marshland occurs.
Soil in the swamp forest (e.g., Mississippi River sediment) is composed largely of clay (38 percent), which is extremely fine and therefore has more surface area than soils composed of coarser particles. Surface area of soils affects their capacity to retain various chemical compounds including heavy metals. Swamp soils in the study area have a concentration of some heavy metals (copper, zinc, and nickel) higher than any of the other environmental units, although iron and inorganic chemical compounds such as sulfides are only moderately high in concentration.
During decomposition, detritus (dead organic matter, mostly plant) releases inorganic nutrients that are required for primary production (nutrients are required for the decomposition process as well). These nutrients accumulate in soils prior to being used by future generations of plants. Nutrient turnover rate (the rate at which nutrients are cycled through the system) is usually quite rapid in hot. damp systems such as s~o]amp forests. where nutrients are used up soon after being released into the soil. Decomposition of litter occurs so rapidly in the m.,amp forest (and in tropical rainforests) that no buildup of organic matter (detritus) occurs on the forest floor. Soil chemistry is closely related to the flooding regime, which affects the composition rate of detritus and the inorganic oxidation~reduction reactions.
Significant accumulation of nutrients in wetland waters usually occurs after a system has been disturbed as by impoundment, a distur-bance that induces and prevents normal cyclic plant growth. Consequently, changes in flooding patterns affect the organisms that reside in an area and alter entire communities. In a recent study of swamp forests in Florida, Carter et al. (1973) found that drainage of the cypress forest initiated a canopy~thinning process
~
that led to greater light penetration to the forest floor. The drier ,,,as unfavor~ able for litter decay and litter accumulation accelerated. Net primary production was reduced
40 a or threat to
Autotrophs and Primary Production In the swamp forest system in the des Alle~
mands area, four general categories of plants are found: trees, vines, herbs, and epiphytes.
Trees dominate total plant biomass, and, by occupying the upper level of growth, filter out most of the sunlight impinging on the system (only one~twentieth of the solar energy that strikes the canopy reaches the forest floor at peak leaf stage). A major portion of tree biomass, however, is composed of woody structural material that does not photosynthesize. Mean standing biomass of all autotrophs in the wetland portion of the swamp forest in the study area has been estimated to average about 3.5 Ib/ft 2 , of which trees make up the major portion.
True swamp forest, the more frequently inundated portion of the wetland, contains in addition to cypress and tupelo gum, swamp maple, and pumpkin ash, and a number of woody shrubs such as Virginia willow and button bush. The areas that are slightly drier than the cypresstupelo gum swamps contain more diverse communities of swamp maple, tupelo gum, boxelder, cottonwood, and black willow. These communities are termed bottomland hardwood forests. Along the margins of old stream courses, bald cypress tends to fringe the streams along with swamp privet, water locust, and water elm. The natural levees, which are just slightly higher, yield red gum, over cup oak, bitter pecan, persimmon, hackberry, and cherrybark oak.
Conner (1975) has determined frequencies of occurrence of tree species for cypress-tupelo gum swamp forest and bottomland hardwood forest in the des Allemands swamp area. Most frequent tree species are given in Table 1 for both types of stands.
The most abundant forms of nonwoody vegetation in the swamp forest are climbing vines. Poison
ivy, Evening trumpet flower, Greenbrier Silva manso
'18
_~,_--c,= __ "",---=--= __ ~ ___ =_""~~=~_~====--=-==-'~-"==~~~ -~~=--="'=7~~=~~-,-~--==.~-=.,-.--,=~ _~_
Table 1. Percentage of tree species in cypresstupelo gum swamp and bottomland hardwood forest of the Barataria Basin.
Cypress-Tupelo Gum Swamp Taxodium distichum (Cypress) Nyssa aquatica (Tupelo gum) Acer drummondii (Swamp maple) ~inus tomentosa (Pumpkin ash)
Bottomland Hardwood Forest Acer drummondii (Swamp maple) ~a aquatica (Tupelo gum) Acer negundo (Boxelder) Populus heterophylla (Cottonwood) Taxodium distichum (Cypress) Cornus drummondii (Roughleaf'dogwood) Salix nigra (Black willow) Ulmus americana (American elm) Carya ovata (Shagbark hickory) Fraxinus tomentosa (Pumpkin ash) Quercus nigra (Water oak) Celtis laevigata (Hackberry) Diospyros virginiana (Persimmon) Ilex decidua (Deciduous holly) Quercus shumardii (Shumard red oak)
33.33 32.41 19.44
8.33
25.00 11.43
7.86 2.86 4.29 8.57 5.71 5.00 4.29 3.57 2.14 2.14 3.57 2.86 2.14
Source: W. H. Conner. 1975. Productivity and composition of a freslnl7ater swamp in Loulslana. Master's thesis, Louisiana State University. Baton Rouge, La.
and cordata are only a few of the types of vines found. Epiphytes, or nonrooted attached plants are also very conspicuous, Spanish moss and Mistletoe being the most notable representatives. Ferns and lichens on trees are also common,
LIte laLLer have been suggested important in
Herbs that grm" on the swamp forest floor are not abundant because of combination of
periods of inundation and reduction of by the canopy of tree leaves.
Primary Production and Primary Consumption Calculation of the average annual productivity
of the wetland portion of the swamp forest system was estimated at 0,20 lb/ft 2 (Burns, unpublished data). Turnover of carbon presumably occurs every 20 years, as derived by dividing total s stock (4 Ib/ft 2) annual pro-duction (0,20 Ib/ft 2)
Net primary production the energy that drives the entire system. Two major energy pathways are used for the distribution of organic carbon: (a) grazing of living plant material by herbivores, and (b) ingestion of dead plant matter (detritus) by detritivores, Wetland systems in general seem to favor the latter pathway; that is, they are generally detritusbased systems rather than grazing systems. The swamp forest in the study area is no exception to this pattern; it is estimated that at least twice as much energy enters the food web via litterfall as is grazed directly. Litterfall occurs in pulses rather than evenly through the year, and peak litterfall in the study area occurs in early winter.
Energy not consumed within the wetland proper is exported to the waterbodies; this exportation process is described below. Quantification of the standing stocks of primary consumers is at this point extremely crude, but one important member of the herbivore group includes an insect, the forest tent caterpillar (Malacosoma disstria). This ravenous larval insect was observed in the des Allemands swamp area during the first week of April 1974. It was observed feeding on tupelo, maple, willow, and cypress leaves but concentrated mostly on tupelo. These caterpillars have been estimated at densities up to 365 animals per m2• In three weeks, few caterpillars could be found, but the tupelo trees had been almost completely defoliated. This defoliation often reoccurs several times in a year.
The tent caterpillar represents what is perhaps a very important mechanism for moving plant carbon from the tree canopy to the forest floor, packaged in small fecal pellets that are still green as they drop. There is some evidence that such grazing insects in forests actually stimulate tree production. They certainly move organic carbon to the forest floor during spring,
20
a time when very little litterfall occurs. Other herbivores (grazers) include deer,
which according to published estimates may occur in densities of up to 1/30 per acre; rabbits, up to 1/3 per acre; squirrels, 1/4 per acre; and also many small rodents and seed-eating birds (the latter comprised by migratory forms).
Detritivores are of greater functional importance than are grazers in the wetland portion of the swamp forest system since detritus represents the major energy flow pathway. Detritivores in this system consist of a variety of organisms including insects, crustacea, microbiota, and fungi. The intensity and importance of the function of detritivores cannot be overestimated, as shown by the lack of detritus buildup on the forest floor.
No quantitative estimates of the relative contribution of various detritivores in terms of' biomass are available, but crawfish seem to represent the most important macroscopic detritivore in the system. These animals mechanically shred leaves after they fall, thereby increasing leaf surface area and consequently hastening further decomposition by the microbial community. Other crustacea, notably freshwater amphipods and aquatic insect larvae, are also important in the fragmentation process.
The utilization of detritus energy seems to consist of a cycle of ingestion by detritivores followed by egestion of unassimilated cellulose material, which is then attacked by bacteria. The particles are enriched by the bacteria converting cellulose into bacterial biomass rich in protein. Often these enriched particles are then reingested by detritivores and converted into animal protein, available in turn to higher trophic levels via predation.
The microbial community in sediments on the swamp forest floor is partly made up of cellulosedecomposing bacteria critical to the mineral-ization of material, but other physiological types are present in abundance; are also very important.
Termites are extremely important detritivores in tropical rain forests and may function in the decomposition of woody litter in the swamp forest system under study, especially in those areas flooded less frequently.
At least two factors prevent the complete denudation by grazing species of all green plants in any natural ecosystem. One factor is an adaptive (evolved) process which different
produce chemical by-products either ous or unpalatable to many prospective grazers. The other factor involves the continuous ion on herbivores by carnivorous species. In general, total biomass of the predatory trophic level is far lower than is the standing stock of herbivores. However, the small upper trophic level is important for the continued existence of the natural system. Disastrous population explosions of grazing species have often accompanied the destruction by man of predatory species. Predatory species are generally the most sensitive to perturbations of a system, partly because they exist at the lowest densities and partly because they are often relatively specialized.
Carnivores in the wetland portion of the swamp forest system include spiders and voracious insects such as dragon flies that prey on other insects; reptiles, including snapping turtles, snakes, and alligators; mammals ranging in size from bats and shrews to bobcats; and insectivorous birds and raptorial birds, especially barred owls. Reptiles and amphibians are represented by more species in the swamp forest than in any other wetland subunit.
Swamp Forest Associated Water Bodies
The constantly flooded portion of the swamp forest system consists mostly of bayous and accounts for only a small percentage of the des Allemands system along the proposed pipeline route. In general, these waterbodies are sluggish, turbid, eutrophic systems. The lakes adjacent to the swamps are rapidly filling in with rooted plants and organic sediments in the classic patteTn of lake succession. For example, Lake Boeuf has markedly decreased in area and depth in recent years.
Waterbodies comprise considerably less of the total area of the swamp forest system than in other wetland systems in the study area and are thus less important in terms of total organic
tion. Instead the vital
22
function of conduits of excess swamp forest production. Rainfall floods the entire system, and excess water flows slowly over the swamp forest floor, carrying with it detritus particles, organic decomposition products, and inorganic nutrients, and depositing them into bayous intersecting the wetlands.
Primary Production Primary production in the bayous is the
result of (1) rooted aquatic plants such as coontail and fanwort found along the edge of the bayou; (2) floating and emergent aquatics, the most important being duckweed, water hyacinth, smartweed, and alligator weed; and (3) phytoplankton. The latter group is prevented from significant production bec~use of reduced light in the water column owing to shading by overhanging trees and floating plants and by the load of serliment (organic and inorganic) in the water. Consequently, waterbodies in the swamp forest system are heterotrophic, with total consumption exceeding total production (the bayous more so than the lakes).
The higher trophic levels within waterbodies are supported primarily by detritus exported from the swamp forest floor. This export on an annual basis has been estimated at 0.04 lb organic matter per ft 2 uf wetland. The large quantity of animal protein harvested annually from swamp forest ,.,aterbodies is thus directly a function of swamp forest wetland production rather than primary production within the waterbodies. Disruption or destruction of wetland production would therefore be reflected in reduced fishery production. This excess production washed off the swamp forest floor into the waterbodies is also exported from the s\vamp area to habitats to the south.
Awareness of this process of of matter from the swamp forest of
the Barataria Basin to the lower marsh areas is necessary for a full appreciation of the integrated nature of the Barataria ecosystem. Day et al. (1976) calculated the exportation of organic matter, nitrogen (as NH4-N and N0 2 + N0 3), and phosphorous (as available P04) from the des Allemands basin, taking advantage of the fact
that approximately 90 percent of the water leaving the des Allemands swamp is carried by Bayou Chevreuil (the remainder flovling down Grand Bayou). Estimates for annual exportation from the upper basin were about 9,900 tons of matter, 940 tons of n1tro8~n. Rnd 140 tons of phosphorous. This organic matter and nutrients are carried into the marsh areas where they can be used for further primary production or for consumption by marsh species.
In essence, the system of waterways connecting the various units of the whole basin acts in a manner similar to the circulatory system of man. Just as the blood carries food and oxygen to the body's cells, the bayous and tidal streams of the basin distribute organic l:1atter ane nutrients to the myriads of species forming the complete system. If something happens to damage the lungs, the entire body is affected because of a lack of blood~carried oxygen. The damage may occur over a long period of time, and deterioration of the lung may not be understood as the cause of the body's loss of vigor. Likewise, damaging the productive capacity of the des Allemands swamp forest will have long-term effects on the productive capacity of the entire Barataria system, even though the effects may not be readily visible and direct.
Primary Consumption The most important primary consumers in the
swamp forest waterbodies, both in a functional and economic sense, include crustacea such as amphipods, grass shrimp, and crawfish; flat worms and segmented worms; insect larvae; mollusks; and finfish, as well as the microbial community on which most detritivores depend for the nutritional enrichment of otherwise unassimilable celluloserich detritus. Another important group easily overlooked is the meiofauna, the community of minute animals living within the sediments beneath waterbodies. Amphipods appear to dominate, both in numbers and biomass, the detritivorous community in swamp forest waterbodies.
Predation The upper trophic levels in swamp forest
waterbodies contain a '!;vide variety of animals insect larvae such as
23
24
~~~~~--~~~~~~~~~~~~~~~
ton such as rotifers and waterfleas, and nekton or actively swimming shellfish and finfish. One of the most prominent carnivores in swamp forest waterbodies is the catfish, which is estimated to occur at a density of up to 150 fish per acre of waterbody. Amphibians such as frogs, swimming reptiles such as water snakes, cottonmouth moccasins, turtles, and alligators, and swimming mammals such as otters also obtain at least a portion of their food within the swamp forest waterbodies. Diving birds, such as kingfishers, and wading birds (herons and egrets) often feed along swamp forest bayous as well. (See Survey of Coastal Organisms.)
Man's uses of aquatic animals from the bayous include many forms, notably the harvesting of crawfish, bowfin~ bass, and catfish. In the des Allemands system (104 mi2 of wetland and waterbodies) 2.5 million pounds of catfish were harvested in 1961.
Differences between bayous and lakes in the swamp forest system are related to the edge effect, as shown by the smaller relative area of interface between wetland and waterbody in the case of lakes. This results in the reduction of eutrophic conditions in lakes in comparison with bayous since organic material is added at a lower rate in lakes than in bayous. Phytoplankton levels are higher in the lakes, and as a result. primary production there is more significant, although the lakes in the swamp forest system are still considered heterotrophic. Lakes such as Lac des Allemands serve in a sense as water treatment systems or oxidation ponds, in which organic-rich water from the swamp forest proper is exposed to atmospheric oxygen and biological oxidation removes dissolved organic material.
or
Bald The bald cypress is extremely as timber because of decay resis·~
tance, its very slow growth rate, and its beauty.
Tupelo gum: Gum grows faster than cypress and
E; ....
makes good timber since it is generally tall and straight,
Crm"fish: The crawfish is harvested in quantity the swamp forest study area and is commer-
cially as a food item. It is also an i.mport;:mt food item for many game fish including largemouth bass.
Pest insects: Of direct importance to man are the blood-sucking insects, mostly members of the order Diptera (true flies), These insects often have an aquatic stage in their life cycle and occur locally in all wetland areas from the swamp forest to the salt marsh, Various mosquitoes, gnats, green head flies, etc, attack both man and domestic animals. The forest tent caterpillar, which affects the tupelo gum and other trees used by man, also qualifies as a pest species (although its role may in some ways be beneficial),
Catfish: Although several species of catfish are harvested from waterbodies in the swamp forest and fresh marsh areas, the blue catfish and channel catfish are probably most important as a commercial food item.
Other finfish: Miscellaneous fish harvested in swamp forest waterbodies include largemouth bass, bluegills, black crappies, and bowfin,
Alligators: The alligator, which has been considered rare and endangered until recently because of overharvesting, is now making a comeback, and population in the des Allemands swamp forest area in 1973 appeared good.
Mammals: Swamp rabbits, deer, raccoons, and nutria are all hunted or trapped to some extent in the swamp forest study area,
Osprey: Fish hawks are rare in Louisiana and have been seen in the des Allemands swamp forest area. These birds are on the "blue list" of declining species of birds,
Red-shouldered hawk: Included on the blue list of declining species, this hawk has been seen in the des Allemands swamp basin,
25
26
The fresh marsh portion of the Barataria Basin lies primarily between the natural levee systems of the Mississippi River and Bayou Lafourche, beginning around Lac des Allemands and Lake Boeuf and reaching seaward to the points where the Intracoastal Waterway crosses the basin. The major waterbodies in this area are Lake Salvador and Lake Cataouatche.
In the Barataria drainage system, 223,488 acres of fresh marsh comprise approximately 19 percent of the wetland of the basin. In terms of area, waterbodies are probably more dominant in the fresh marsh area than in the swamp forest region, but are less dominant than in the seaward brackish marsh zone.
Marshland may in general be defined as a periodically flooded zone characterized by primarily nonwoody vascular plants. Freshwater marsh is somewhat more ambiguous and less readily defined than is the swamp forest unit or any of the other wetland units except perhaps the brackish marsh (fresh and brackish marshes merge almost imperceptibly) since the freshwater marsh is the most diverse in terms of numbers of plant associations.
Much of the freshwater marsh environmental unit is represented by flotant or floating marsh. Flotant consists of a dense mat of vegetation supported by detritus several feet thic.k, which is held together by a matrix of living roots. This floating marsh is indistinguishable from true wetland until trod upon and extends from the true shoreline of a lake into the lake itself. Eventually, as the bottom sediments and the floating layer each accumulate more material, they merge to form a ne,., shoreline and the lake shrinks in size.
Typical marsh wetland in the freshwater marsh area is described below, beginning as before with sediment eompnsition and the auto trophic component on "lhich the total unit is energetically dependent.
Chemical characteristics of soils in the freshwater marsh zone both regulate and are regulated by the kinds of autotrophs making up
the plant community. One of the most obvious differences between swamp forest wetland and freshwater marshland is the increased thickness of organic sediment in the latter. Coastal marsh soils are of too recent to have
, or horizons such as are found in the recent Hississippi alluvial soils of the swamp forest system.
Detritus deposited on the surface of the fresh marsh remains partially undecomposed in some areas, resulting in a buildup of peat. Clay content of freshwater marsh sediment is slightly lower than in the swamp forest system, averaging about 33 percent. Organic content is approximately 65 percent, or double that of soils in the swamp forest. Sulfides, mlUally proportional to total organic content, are also relatively high in the freshwater marsh soils as are heavy metals such as copper, lead, zinc, mercury, iron, and manganese. The abundance of all such trace elements is a function of the hydrologic regime of the area and serves to ensure adequate supplies for autotrophs that require small amounts for normal growth and development, as do all living components of an ecosystem.
Autotrophs and Primary Production In the total fresh marsh maidencane or
paille fine is dominant and covers about 34 percent of the total wetland. Spikerush and bulltongue are also common, but the latter is found as well in slightly brackish or intermediate salinity marshes, and its presence in a given area is considered evidence of occasional saltwater intrusion. Within all marsh types the growth patterns of different species vary, especially in the freshwater marshes, which are characterized by more plant species and groups of associated species than other marshes.
The percentage of occurrence of plant species in fresh marsh portions of the Barataria Basin are shown in Table 2.
At present not enough is known concerning physiological requirements of individual species to explain their distribution patterns; however, these patterns are undoubtedly a reflection of slight local differences in physical conditions such as elevation, inundation time, nutrient abundance, etc.
27
28
Table 2. Percentage of plant species in fresh marsh portions of Barataria Basin.
Panicum hemitomon (Maidencane) Sagittaria falcata (Bulltongue) Eleocharis sp. (Spikerush) Alternanthera philoxeroides (Alligator-weed) Cyperusodoratus (Sedge) Typha spp. (Cattail) Echinochloa walteri (Water millet) Eichornia crassipes (Water hyacinth) Bacopa monnieri (Water hyssop) Polygonum sp. (Smartweed) Scirpus olneyi (Three-cornered grass) Zizaniopsis miliacea (Giant cutgrass)
41.35 17.42 12.31
3.43 3.21 2.59 2.15 1. 99 1.82 1.60 1.48 1.36
Source: R. H. Chabreck, 1972. Vegetation, water, and soil characteristics of the Louisiana coastal region. Louisiana State University Agr. Exp. Sta. Bull. No. 664.
In all marshes there are three major groups of autotrophs: standing vegetation (mostly grasses with some broadleafed forms), epiphytes (microscopic algae on the surface of the vascular plants), and benthic algae (usually diatoms living on or in the marsh sediment), The latter group increases in significance during the winter months when the standing vegetation dies back allowing more light to impinge on the sediment. Epiphytes can significantly augment primary production year-round, in some cases producing more organic carbon than the "host" plants to which they are attached.
Net annual production for the entire wetland portion of the freshwater marsh system in the study area is roughly estimated (from limited data) to equal that of the swamp forest system (0,22 Ib ) this estimate could eas be 10v1 by a factor of three in certain areas. The fresh marsh may provide a nearly ideal environment for the emergent plants occurring there, since it provides a continuous water supply without the occurrence of the salt that presumably taxes plants in the saline marshes by
r I , £:
forcing them to expend energy, constantly pumping out excess salt from their tissues.
Production in freshwater marshland is season~ al in nature, with peak growth occurr during May and June vThen nutrients are in abun~ dance from the decomposition of the previous year's crop, sunlight is most direct, and the photoperiod is maximal. Nutrients in waters flooding the freshwater marshes decrease sharply in the spring during peak grm'7th, presumably because of uptake by plants. Total live above~ ground biomass of the autotrophic community is estimated to equal about 8,000 lb per acre in the freshwater marsh system.
Since the freshwater marsh system is gener~ ally beyond the most inland area significantly affected by tidal water level change, it is also restricted from the benefits derived from such "free work" as tidal flushing, stirring, and removal of litter, all of which accrue to marshland closer to the Gulf. Rainfall provides most of the flushing action in freshwater marshes. Occasionally prolonged southeasterly winds back up water in the entire wetland system until the marsh is covered.
Both swamp forest wetland and brackish marsh wetland are characterized by vegetation structurally more resistant to erosion during the winter than some of the dominant vegetation in the freshwater marsh area. During late fall the upper parts of broadleafed plants like bull tongue die back and disintegrate completely. Roseau cane, however, seems to remain in place, although its dead standing stalks are more open and not as dense as the nonliving portions of salt marsh grass. The freshwater marsh areas dominated by bulltongue appear strikingly barren during the . winter months, in comparison with their lush green appearance in midsummer. Production by macroscopic vegetation thus appears to shut down almost completely during the winter.
Water movement appears to stimulate marsh production, and growth of emergent vegetation is almost always more extensive (taller and denser) at the edge of waterbodies than further into the marsh. Water movements in fresh marshland are related to gradients set up by rainfall patterns and the speed at which coastal wetland drains off
29 .... --------------------------------------------------------------------~
30
excess water to its downstream marsh unit. Very little gradient occurs across the entire freshwater area, so currents are usually sluggish in most areas.
Primary Consumers In all Louisiana wetland systems, including
freshwater marshes in the Barataria Basin, herbivores appear to occupy a less prominent functional role than do detritivores, since the primary pathway of energy flow from producers to consumers in each system is via detritus. Of the grazers in the fresh marsh, however, insects could be the most important, ingesting probably more than 5 percent and perhaps up to 10 percent of net plant production (live), It is unfortunate, therefore, that practically nothing is as yet known of the insect component of the fresh marsh area, even though the insect community is probably simpler (composed of fewer species) than in more spatially diverse areas.
Of the few large herbivores in the system, nutria are probably the most significant, while muskrats are much less abundant than in more saline marsh systems. The plants that muskrats prefer (brackish marsh grasses such as threecornered grass) do not occur in fresh marshes, and muskrats were estimated to occur at a density of only about O~06 animals per acre. Nutria, however, do better in fresh marshes than in any other marsh type, since they feed on maidencane, bulltongue, cattails, pickerel weed, and water hyacinth. Nutria were trapped during one year in fresh marsh at a maximum rate of about 0.9 per acre, \vhich represented a minimum estimate of their total density since all animals are never trapped. Deer have been observed grazing the fresh marsh area and are estimated to occur at a density of about 0.007 animals per acre (or one animal per 142 acres). Frpsh mRrsh has also been estimated to be of suppar one rabbit per acre, which is a greater density than rabbits occur in any of the oth~r wetland however most rabbits reside in slightly elevated areas such as spoil banks, and should not contribute significantly to grazing of marsh vegetation. Total grazing by all larger herbivores probably removes less of the net living primary production than does insect ingestion.
Detritivores Detritivores in the fresh marsh vJetland
include most notably small crustacea (amphipods and mysids). vlhieh the role of detritus carried out by crawfish in the swamp foresL These detritivores occur primarily at the interface bet~"een vletland and waterbodies and could be considered members of either marsh component, Microbial forms in the fresh marshes (and all wetlands) represent the function~ al complement of the "shredders"; that is, bacterial populations are enhanced by increased surface area (substrate) resulting from mechanical shredding, thereby hastening the conversion of detrital carbon to bacterial carbon with its increased nutritional value to detritivores as w·ell as higher forms of heterotrophs, Through this cycle dead plant tissue is transformed into high quality animal protein. Bacteria appear to show two peaks of abundance in freshwater areas, in spring and fall. It is thought that temperature in part determines the rate of colonization of peat particles in freshwater areas. Vegetation types seem to determine the density of various bacterial forms; e.g., cellulose decomposers are often relatively dense· in peaty soils.
Fungi undoubtedly also contribute significantly to detrital degradation in freshwater marsh.
Four possible fates await the organic carbon produced within this system: (1) some dies in place and is deposited as incompletely decomposed detritus (peat); (2) some dies in place and enters the detritivore cycle described above; (3) some is grazed (live) by herbivores and subsequently turned into carnivore flesh; and (4) some is partially degraded and exported by rainfallinduced currents to waterbodies draining the marsh.
Carnivores Of those animal species responsible for
shunting energy into the third (or higher) trophic level, the following groups are important in the fresh marsh wetland area: 1) Predatory insects and spiders 2) Reptiles and amphibians 3) Insectivorous and raptorial birds Ij)
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Practically nothing is known about either herbivorous or carnivorous (or parasitic) insects in marshes in general, although the density of biting flies and mosquitoes in some marsh areas makes them seem very important to man. Those predatory insects that are functionally most important, however, would be the species that help maintain a check on such grazing species as grasshoppers.
Reptiles and amphibians in freshwater marshes are represented most dramatically by the alligator, which is not present in great abundance in the Barataria Basin. Of the fewer than 10 other species of amphibians and reptiles identified in the fresh marsh area, most seem to occur in the brackish marsh as well and, in fact, alligators seem to favor the latter marsh area. Most of the reptilian species are seen primarily on elevated areas such as levees and spoil banks, rather than in the marsh proper. .
Carnivorous birds in the fresh marsh area include: (a) insect eaters, such as marsh wrens, yellowthroats, egrets, and blackbirds; (b) wading birds and fishing birds such as bitterns and gallinules, herons, and egrets; and (c) raptorial birds, such as marsh hawks.
Other predatory animals in the fresh marsh area include: (a) snakes that feed on crawfish, fish, and amphibians; (b) mink, which feed on snakes) frogs, insects, herbivorous mammals, and birds, as well as fish; and (c) raccoons, which are omnivorous, eating insects, reptiles, shellfish and finfish, and plant material (see Survey of Coastal Organisms for further detail).
Waterbodies of importance in the freshwater marsh area of the Barataria Hasin include Lakes Cataouatche and Salvador and and canals. Detrital material and dissolved nutrients washed into fresh marsh area waterbodies support food webs in the \vater column similar to those that occur on the wetland component.
Primary Production and Organic Input from Wetland
Since waterbodies in the fresh marsh study area are generally proportionally small in relation to wetland, their function to the is that of a conduit of material Lo more cloW!lstream areas. Primary production in fresh marsh bayous is overshadowed by a high concentration of organic material exported from the wetland proper. The system is both highly eutrophic and heterotrophic, and dissolved oxygen is usually low, Nutrient concentration in the water column seems slightly lower on the average than in bayous within the swamp forest, but not significantly so. The water is turbid and ill suited for optimum phyto~ plankton growth. The percentage of occurrence of aquatic plant species in fresh marsh areas of the Louisiana coastal zone in general is given in Table 3 (no data are available for Barataria Basin alone).
Table 3. Percentage of aquatic plant species in freshwater habitats for the Louisiana coastal zone in general.
Lemna minor (Duckweed) 15.26 Eleocharis sp. (Spikerush) 11.27 Ceratophyllum demersum (Coontail) 11.15 Myriophyllum spicatum (Eurasian watermilfoil) 11.03 Char a vulgaris 8.10 Utricularia cornuta (Horned bladderwort) 5.99 Najas guadalupensis (Southern naiad) 5.75 Nymphaea odorata (White waterlily) 4.93 Eichornia crassipes (Water hyacinth) 4.93 Cabomba caroliniana (Fanwort) 3.64 Potamogeton pusillus (Slender pondweed) 2.70
Source: R. H. Chabreck. 1972. Vegetation, water and soil characteristics of the Louisiana coastal region. Louisiana State University Agr. Exp. Sta. Bull. No. 664.
Similar forms of phytoplankton and floating aquatics occur in fresh marsh waterbodies as in the swamp forest bayous since the clistribution of
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aquatic plants is often strictly dependent on individual salinity tolerances. Diversity and production of aquatic plants are partially controlled by both turbidity and flow rate; for example, water hyacinth and water lettuce only do well in sluggish areas. Many species of algae found in the waterbodies are probably washed out from the marshland proper.
Species diversity of phytoplankton is greater in the bayous and ponds of the swamp forest and fresh marshes than in other wetland types. Peak phytoplankton diversity seems to occur in August, but this pattern is based on few samples and phytoplankton is notoriously patchy in distribution. The most numerous forms are diatoms and blue-green algae; the latter forms often reflect generally eutrophic conditions.
Primary Consumers Herbivores and detritivores in fresh marsh
associated bayous are somewhat similar to the forms represented in the swamp-forest waterbodies, namely zooplankton, and some nektonic forms; benthic animals including meiofauna; crustacea such as grass shrimp representing detritivores; and waterfowl.
Among the zooplankton, cladocera (water fleas, typical freshwater crustacea) and rotifers are in fresh marsh waLerboJies. These strictly freshwater species are accompanied by freshwater copepods and, occasionally, brackish water copepods. During spring and fall the zooplankton population seems to peak in freshwater marsh bayous.
Little is known of benthic fauna in the freshwater marsh unit. although crml7fish and freshwater shrimp are sometimes included in the benthic category. As salinities increase toward intermediate and brackish areas such mollusks as brackish1ili:lter clams (shells of this have been used
. for roadbuilding in Louisiana). An edge effect of enhanced biological
activity at the edge of a waterbody that is noticeable throughout the entire Barataria Basin applies to freshwater bayous since most benthic forms occur near the interface between marsh and bayou. Exposed root material of emergent vegetation at the edge of a bayou is often found
teeming with amphipods. Amphipods assume even more importance in waterbodies in more saline marshes since aquatic insects out of the conununity of detritivores.
Nekton, in show a ance for to migrate long distances. This migration is especially important in true estuarine areas but also affects freshwater marsh areas since it is common for typically marine forms such as menhaden to migrate into freshwater areas. Herbivorous nekton important in the freshwater areas include carp, sheep shead minnow, and the wide-ranging menhaden.
In terms of the entire state of Louisiana, waterfowl (puddle ducks and diving ducks) are predominantly associated with fresh and brackish marshes; however, in the area under consideration this pattern is somewhat aberrant, since much of the local contingent of waterfowl are at present attracted to a brackish water impounded area near the seaward end of Bayou Lafourche. Puddle ducks are usually found in shallow ponds where their preferred food items, such as widgeon grass, occur. Diving ducks prefer deeper lakes (see section on birds).
Carnivores The uppermost trophic levels in fresh marsh
waterbodies include (as in the swamp forest) catfish, bowfin, bluegill, gar, crappie, bass, water snakes, and some occasional marine migrants such as blue crabs (which, in some respects, could perhaps be better classified as detritivores).
Wading birds such as great egrets seem to remove large but unknown quantities of primary consumers from fresh marsh bayous. These birds have been seen to migrate periodically between fresh marshes and more saline marshes nearer to the Gulf.
Reptiles, amphibians, and mammals presumably contribute the same (unknown) proportion of predation in fresh marsh and swamp forest water bodies, although alligators should be more important in the fresh marsh (see separate sections for detailed discussion of these vertebrate groups).
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Organisms of Special Interest or Economic Significance to Man
Water hyacinth: As the water hyacinth was introduced to Louisina, it has few natural enemies. It has become a pest species in sluggish waterbodies in the swamp forest and fresh marsh since it clogs the water surface and makes boat travel difficult. A recent shortage of the herbicide 2,4-D, which has been used in some areas to help control the plant, seems to be exacerbating the problem.
Puddle ducks: Valuable game birds, puddle ducks are prized by hunters and would normally be found mostly in fresh marsh waterbodies; but in the Barataria Basin much of the total population is displaced by the presence of a brackish water impounded area near Bay Champagne. This area is presently producing widgeon grass, the favorite food of these ducks.
Marsh hawks: The predatory marsh hawks normally occur in all marsh types and have been seen in the study area. They are declining in numbers and are, therefore, included on the blue list of declining species.
Alligators: Alligators should become abundant during the next few years since their population now is being regulated and protected.
Nutria: Since its introduction to Louisiana in 1949, nutria has become an important fur species and is trapped in some quantity.
Other mammals: Mink~ raccoons, otter, and muskrats are also trapped for fur in the fresh marsh area. Raccoons and opossums are also eaten by man. Muskrats are less abundant in fresh marsh than brackish marsh areas.
Catfish: As in the swamp forest waterbodies, catfish are harvested in quant from fresh marsh and lakes. The blue caLfh!ll and channel catfish are the most finfish species caught for food in fresh marsh waterbodies.
Other finfish: Bluegill, Largemouth bass, Black crappie, Bowfin, Pirate perch, Spotted sunfish, Carp, and other miscellaneous fish are also caught in fresh marsh waterbodies.
Brackish Marsh and
Between the freshwater and marine ends of the Barataria drainage basin is situated perhaps the most environmental unit, at least from a theoretical standpoint. This is the brackish marsh area, which a true intermediate zone in several other th:::lD just salinity.
Evidence from many studies in different latitudes has given rise to an ecological ru1e~ of-thumb that aquatic areas that are the most stable (unvarying) with respect to their physical characteristics, especially salinity and temperature are likely to show greater species diversity than areas of rapid change. Estuaries are defined loosely as inland bodies of water intermediate between fresh and saline systems and, therefore, mixing ;lones. They are also notoriously unstable (variable) in terms of salinity. Estuaries extend into the brackish marsh unit of the study transect, thus making the whole system a transitional zone.
The brackish marsh system represents the first unit strongly influenced by tidal effects. Both previously discussed units are characterized by predominantly unidirectional water movements resulting from rainfall runoff. In the brackish marsh, however, water level and salinity are also influenced by the level of Gulf waters at the coast, whether this level results from high tides or storm surges. This "back up" effect produces a complex pattern of water level change in the brackish marsh.
In the Barataria Basin there are approximately 229,824 acres of brackish marsh (including intermediate marsh, an additional category sometimes delineated between fresh and brackish marsh). This comprises approximately 20 percent of the wetland area of the entire basin. There is a significantly higher proportion of water surface than in the freshwater wetland areas to the north.
This brackish marsh area forms a band that stretches across the drainage basin from below the Intracoastal Waterway to the salt marsh fringing Barataria Bay and the many lakes and estuaries leading into it (Fig, 1), In the center of the basin, this band of brackish marsh is 15 miles wide off as
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it approaches the Mississippi and Bayou Lafourche to either side. The major bodies of water in this region are Little Lake~ Turtle Bay, and Bayou Perot.
Trophic (energy flow) relationships in the brackish marsh system are basically similar to the patterns already described for the two freshwater systems. The entire system is still considered to be detritus-based. Major functional components are described below, first for the wetland proper and then for the associated waterbodies, now considered estuaries.
Brackish Marsh Wetland Proper
Soils of the brackish marsh unit are intermediate in clay content (16.5 to 30 percent) between swamp forest soils and the nearshore sandy sediment. In terms of organic content, however, the brackish marsh soil shows a higher level of both organic carbon and organic nitrogen than soils in any other unit (27.7 percent and 1.6 percent, respectively). Sulfides in brackish marsh soils, being closely related to organic content, are also maximal in this unit for the entire basin. This indicates a strongly anaerobic regime (devoid of oxygen) below the surface layer. Heavy metals such as iron and copper, often known to concentrate along with organic debris, are also found at high levels in the brackish marsh area, although usually no higher than what could be considered normal concentrations.
The water saturates the soil and fills the spaces between soil particles (termed interstitial water) to playa crucial role in the complex chemical exchange reaction between sediments and overlying water, Plant nutrient concentrations (nitrogen and phosphorus compounds) were higher in brackish marsh interstitial water than in any other area.
The brackish marsh may be a zone where fine and matter is
trapped. As fresh 'vater flowing seaward encounters higher salinity water. the ionic constituents of the saline water tend to flocculate fine suspended particles in fresh water, which then settle out.
Autotrophs and Primary Production Total overall net primary production for
brackish marsh wetland is estimated to equal about 0.22 Ib/ft2 annually, as in both freshwater wetland systems. This estimate is the most speculative of all wetland CGti~
mates since in all other vletland types being described there are comparable published estimates from studies on other geographic areas and since almost nothing is known concerning productivity of brackish marsh plants. Primary production even in a more stable and uniform area than brackish marsh seems to vary widely depending on specific chemical and hydrographic features of the environment in which a particular plant species is growing. Also there does not seem to be a constant trend from saline to fresh marshes from which intermediate values could be inter~ polated.
There are, undoubtedly, physiological advantages to marsh plants in freshwat'er areas, some of which have been mentioned above. Likewise, there are ecological advantages to plants in salt marsh environments, related both to tidal flushing and to the lessening of competition from plants intolerant to saline water. Presumably in the intermediate zone a lot of trade-offs occur between relative advantages and disadvantages of both extremes.
Empirical estimates of plant production rates in the brackish marsh have been based on the assumption of a strong positive relationship 'between biomass (amount present at anyone time) and productivity (amount produced over a long period, usually a year). On this basis, the brackish marsh with its dominant producers (wire grass and salt grass) has the greatest live biomass of any marsh type. Wire grass does not grow tall or coarse as fresh marsh species like maidencane or Roseau cane but rather grows in extremely dense stands. Wire grass covers approximately 46 percent of the total brackish marsh wetland area, and significant increase in dominance of a single species over the case of the freshwater marsh area where the dominant species covered about 40 percent of the total area. This exemplifies the decrease in plant
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species diversity that occurs as salinity increases. Wire grass is also dominant in terms of total cover over the entire coastal marsh zone. Salt grass is the second most prominent plant in the brackish marsh wetland and together with wire grass comprises almost 75 percent of the total vegetative cover of the area. Table 4 lists the major brackish marsh plant species and their percent occurrence in Barataria Basin.
Table 4. Percentage of plant species in brackish marsh areas of Barataria Basin.
Spartina patens (Wire grass) Distichlis spicata (Salt grass) Spartina alterniflora (Oyster grass) Eleocharis parvula (Dwarf spikerush) Juneus romerianus (Black rush) Scirpus olneyi (Three-cornered grass)
45.8Lf
28.96 9.03 5.49 3.26 1.26
Source: R. H. Chabreck. 1972. Vegetation, water and soil characteristics of the Louisiana coastal region. Louisiana State University Agr. Exp. StaG Bull. No. 664.
Primary Consumers It has been estimated in the preceding
discussion that herbivorous insects in the wetland freshwater marsh system could remove live plant material equivalent to up to about 10 percent of the annual net primary production. This estimate is based on two points: (1) insects increase in functional importance as salinitv decreases; and (2) insects have heen
of the net to graze over ~
ion in a salt marsh in Georgia. If the assumption of an increase in the proportion of primary production grazed by herbivorous insects in fresh marsh areas is valid, then insects should play an intermediate role in brackish marsh wetlands, i.e., perhaps 7 percent of the net live organic production is siphoned off via this pathway.
Among the larger herbivorous animals in the brackish marsh wetlands, the most conspicuous and possibly the most important is the muskrat, which finds brackish marsh most suitable to its life~ style. These animals have been estimated to maintain an average population density in brackish marsh in the Barataria Basin of 0,6 animals/acre, Assuming that an average muskrat weighs about 2.2 lb, and since muskrats are known to eat at a rate equivalent to their total body weight every 3 days, then each animal must eat about 266 lb/yr. Muskrat density times ingestion rate therefore equals about 0.004 lb/ft2 of primary production ingested by muskrats annually. This is equivalent to about 2 percent of estimated net primary production, which is quite significant when applied to the entire brackish marsh unit. Muskrat population density often exceeds the average figure used here, and overgrazing in some areas has been blamed for local marsh destruction. In addition, grazing by muskrats is often concentrated on root portions of marsh plants (tubers, etc.) rather than on the grass blades above ground, which reduces the ability of the plants to regenerate. Local areas of marsh destroyed by overgrazing by muskrats are known as "eat outs" (see section on mammals for more discussion of muskrats), These prolific herbivores serve as an important node in the food web of the marsh system, being preyed upon by many forms including reptiles, hawks, and mammals.
Rabbits and deer are not as abundant in brackish or salt marshes as in fresh marsh areas, and squirrels are absent. Small rodents such as rice rats are present at unknown densities.
Detritivores The fact that a net buildup of detritus (as
peat) occurs in the brackish marsh area indicates that a large portion of total net production is neither exported nor used by higher trophic levels within the system. Differences between the relative amounts of detritus used in brackish marsh as opposed to fresh or saline marshes are undoubtedly related to the different flooding regimes in each system and perhaps also to dIfferences in plant structure, wire grass being more resistant to out into the estuaries.
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Fewer species of benthic forms, which comprise the majority of detritivores, have been noted in brackish marshes than in other marsh types; however, at this point, data on densities of detritivores in the various wetland portions of marsh systems are not of comparable quality, i.e., more data. is available for salt marsh detritivores than for species in other marsh systems. Nematodes, which represent probably the most abundant meiobenthic organism in sediments across the entire coastal transect and which are an important form of detritivore, made up about 60 percent of total numbers of animals found at the edge~ of brackish marsh estuaries. Amphipods, another extremely important detritivore group, are also abundant.
The brackish marsh area is widely used by penaeid shrimp (both brown and white) as extended nursery grounds. Both species immigrate from offshore into the wetlands while still in the postlarval stage. Here they become widely dispersed from saline to fresh marsh areas. They metamorphose to the juvenile life stage, settle to the bottom sediments, and become an important member of the benthic community, feeding mostly on organic material produced by marsh grass decomposition.
Much remains to be learned concerning the areas of wetland that are most valuable as nursery areas, but in general white shrimp seem to prefer less saline areas than do brown shrimp. Commercial concentrations of shrimp occur as far north as Lake Salvador during dry years, Both species emigrate offshore from the wetland as ~vater temperatures begin to decline in the fall, and significant numbers of "yearling" shrimp reenter the wetland area the following spring to take advantage of the rich food supply,
As usual, the edge effect, or predominance of act at the interface between marsh and \.mterbodies, to detritivores in
brackish marsh as \'Jell as in all other environ·~ mental subunits,
The microbial portion of the detritivore functional unit in the brackish marsh system appears relatively higher in biomass than in the salt marshes further south, probably because microbial density is generally related to organic levels, which are quite high in brackish areas,
Carnivores Reference has been made to the
of muskrats in energy to the upper trophic levels via an array of
various snakes marsh hAWks~ and mink. Mink have been found to fresh marsh to brackish marsh, bUL they become most numerous in the latter area during periods of peak muskrat density.
Marsh birds in brackish marsh areas become extremely numerous during spring and summer; some species are: King rail, Boat~tailed grackle, and Red~winged blackbird. Some of these birds, such as Boat-tailed grackle, have an extremely varied diet and will eat practically any small animal,
including crustaceans and a variety of insects. Brackish marsh insects An~ also preyed upon by bats and by spiders in addition to other insects.
Brackish Marsh Associated Water Bodies
In the brackish marsh area tidal effects first begin to play a part in determining the frequency and duration of flooding of marshland. Even though a net downstream (seaward) flow occurs, there is also the important effect of the inland movement of water, which not only serves to determine the kinds of vegetation on the marsh wetland but also aids in recirculating nutrients and allows the inland migration of larval forms of estuarine species, many of which are incapable of swimming upstream. Thus, although similar biological processes occur in freshwater bayous and brackish bayous, the latter differ physically in showing some alternating current patterns. Rapid physicochemical changes are characteristic of estuarine areas. Organisms residing in brackish marsh estuaries show remarkable tolerance to these rapid changes, and various physiological mechanisms have developed to allow these forms to maintain stable concentrations of salts in their body tissues.
Primary Production Primary producers in the brackish marsh
estuaries face the same problem as in fresh marsh waterbodies--turbid conditions that
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limit photosynthesis. Floating aquatic plants are not prominent in brackish marshes since those forms that often cover the surface of fresh water bayous and lakes--such as duckweed and water hyacinth--are generally restricted to very low salinity areas. Most frequent aquatic plants in brackish water areas of the Louisiana coast in general are given in Table 5 (data for Barataria Basin alone are not available).
Table 5. Percentage of aquatic plant species in brackish water habitats for the Louisiana coastal zone in general.
Ruppia maritima (Widgeongrass) Eleocharis parvula (Dwarf spikerush) Bacopa monnieri (Water hyssop)
62.69 23.01
4.97
Source: R. H. Chabreck. 1972. Vegetation, water, and soil characteristics of the Louisiana coastal region. Louisiana State University Agr. Exp. Sta. Bull. No. 664.
Brackish marsh waterbodies show a marked difference between summer and winter conditions. During the winter, tides and tidal currents are generally low in amplitude, and waterbodies clear up allowing the growth of several macrophytes adapted to reduced temperature. Large mats of
filamentous green algae sometimes clog the less saline waterways. During the summer higher turbidity levels restrict primary production in the waterbodies to phytoplankton except for the shallowest areas vlhich are colonized by an important benthic diatom community.
Primary Consumers Waterfowl, including the dabbling ducks
prized by hunters, prefer brackish marsh for feeding grounds second only to fresh marsh. The total energetic effect of this grazing is unknown but could be significant in local areas in terms
of plants removed. Diving ducks are also found in the brackish marsh and represent the most numerous group of waterfowl that overwinters in the state (see section on birds).
As in every other wetland in the Barataria Basin, the dominant energy flow in brackish marsh waterbodies goes from the emergent macrophytes (grasses) to the upper trophic levels via detritus washed into the estuaries. Some of this detritus is presumably of fresh marsh or even swamp forest origin, and some is locally derived. Approximately the same contingent of detritivores attacks brackish marsh detritus as in the freshwater marsh system, although most insect larvae begin dropping out as salinity increases to be replaced by species of crustaceans not found tn fresh waters. One other group rising to prominence in brackish water areas is the class of segmented worms known as po1ychaetes, so named because of their possession of multiple pairs of bristles or chaetae. These predominantly benthic forms are important detritivores (and sometimes carnivores) in all estuarine and marine systems, especially in areas with fine sediments. Polychaetes represent a major food item of many predacious finfish and other carnivores. Nematodes, ostracods, and amphipods are also quite prominent in the brackish marsh detritivore community.
Among the brackish marsh zooplankton (floating microscopic animals), copepods are most often the dominant form. Acartia tonsa is a copepod species considered to be a typical estuarine form. This cosmopolitan animal, which is probably both herbivorous and detritivorous, serves as food for a great many nektonic species and can hatch, mature, and reproduce in less than 2 weeks.
Carnivores Wading birds seem to have a prominent role
among predators obtaining their food from brackish marsh waterbodies. This group, which includes various egrets, herons, bitters, and ibises, is represented year-round by many forms. The effects of wading birds include recycling nutrients such as phosphorus that are extracted from vmterbodies by feeding and returned to wetlands proper by excrement. This pathway represents one of the
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few feedbacks or reversals in the usual net downstream flux of nutrients. Snowy egrets and Great egrets are the most abundant of ten species of herons and egrets in the Barataria Basin. Migration of wading birds is discussed below under the salt marsh description. Other terrestrial animals that "fish" in the brackish marsh estuaries include such mammals as otters and raccoons, birds such as osprey and kingfishers, and reptiles including alligators and water snakes. Reptiles may generally become less numerous as salinity increases across the coastal transect though populations have not been well sampled. (See sections on reptiles and amphibians.)
The carnivores most often associated with brackish and saline marsh estuaries belong to the nekton category. The voracity of some of these aquatic predators provides sport for a multitude of fishing enthusiasts and establishes a major trophic link between man and brackish marsh primary production. Tides and rainfall patterns both influence the movements of nekton into the brackish marsh estuaries.
Among the finfish species using brackish marsh estuaries for feeding are Spot, Southern flounder, Croaker, Sea trout (speckled trout), and Black and Red drum.
The Blue crab is a decapod crustacean that qualifies as both predator and scavenger and migrates extensively through the entire coastal area, sometimes being found all the VlaY up into the swamp forest system. Blue crab larvae are restricted to relatively high salinities, but young adult crabs are capable of tolerating a wide range of salt concentration.
E
Slilamp
but
or
range from the way to the salt marsh,
will be most abundant in fresh and brackish marshes once the alligator population recovers from over-harvesting.
Marsh hawks: Hawks are found in all marsh types but are declining in numbers and are there~ fore included on the blue list.
Muskrats: Muskrats are valuable fur animals and are more abundant in brackish marsh than in other marsh types, since their food consists of grasses normally found in brackish areas,
Raccoons mink nutria and in brackish marsh
areas. Sport fish: Some typically salt marsh estuary or
marine fish are caught in brackish marsh estuaries, e.g., sheep shead and spot. Other fish caught for food or sport include silver perch and finfish.
Blue crabs: Blue crabs are an extremely valuable food species that are harvested from brackish marsh estuaries in the Barataria Basin as 'JiTell as from saline marsh estuaries and offshore,
Penaeid shrimp: Although only a very small portion of Louisiana's annual shrimp production is harvested within the brackish zone, this area serves as an important (but, as yet unquantified) nursery ground for juvenile shrimp.
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More information is available concerning the salt marsh environmental unit than for any other coastal area. From a geolo~ical perspective, the salt marsh portion of the Barataria estuary is in a senescent (declining) state in which transgression or the gradual inundation of the wetland by marine waters is occurring. This process is gradual from a biological standpoint, and the erosion of previously stored organic material is possibly a factor in the well-known productivity of upper trophic levels in the southern portion of the basin, including the offshore zone. Historically, what is now salt marsh once probably resembled the present brackish marsh area, in which a net peat accumulation still occurs. The boundary between brackish marsh and salt marsh is gradually migrating inland as the whole coastal zone subsides. (For a detailed look at this process of salinity intrusion and its effects on oyster lease locations in the Barataria Basin, see the separately published report on Salinity Changes and Oyster Distribution in this series.)
Characteristics of the salt marsh area are normally more subject to modification by physical processes than are any of the other major units. Tides are diurnal (one tidal cycle per day) and average about I foot, although storm surges produce water levels much higher than the average high tides. A recent study in North Carolina shows that at least on the east coast, winter storms are becoming more severe and numerous (Hayden 1975). Seasonal variation in water level is important (highest average water level occurs in September and lowest from December to March). The wetland in the salt marsh is inundated infrequently during the winter, and winds are therefore critical to marsh flooding during low water-level periods.
In > the salt marsh system, which is most closely affiliated to the physical rpEime characteristic of the Gulf of Mexico, is to an average water temperature greater than 68"F much rainfall, high solar radiation, and low wave energy.
The salt marsh region of the basin surrounds Barataria Bay and its interconnecting water bodies. There are approximately 158,080 acres of salt marsh wetland in the Barataria Basin, com-
prising about 14 percent of the basin's total wetland area. The wetland:water ratio is the lowest of all the considered.
As one flies an aerial transect seaward down the Barataria Basin the shore-line in the salt marsh, \'lhich incl11r1es nll1nprOlJR
water bodies of all sizes ranging from bays to tidal streams and ponds, illustrates the important trend toward increasing total length of edge or interface between wetland and water bodies. The edge effect and its importance to wetland produc~ tivity has already been discussed.
Wet
Chemical parameters of sediments in the salt marsh wetlands of the study area reveal no striking variations or discontinuities from other wetland units, although there are differences related mostly to the higher salinities and to the erosional rather than the depositional character of the salt marsh. Organic carbon levels in the sediment are lower than in the brackish marshes and are similar to values for the swamp forest (about 6 to 9 percent). Sulfides in the marsh sediment \ are similar to values for swamp forest and fresh ) marsh--areas. As expected, heavy metals (especially manganese and iron) are lower in the salt marsh than in other wetland units due to a decrease in clay in the sediment compared to more northerly areas.
Primary Production Of all the major wetland systems, the salt
marsh unit shows the lowest number of plant species; Spartina alterniflora (Oyster grass) covers about 63 percent of the entire salt marsh system and up to 95 percent of the wetland in some local areas. This grass is remarkable for its salt tolerance--it can survive in sediments saturated with water varying from full oceanic salinity to freshwater--but it seems best suited for salt marsh areas where otherwise potential autotrophic competitors are excluded because of their intolerance to salt. Two other grasses are important in the salt marsh unit; Salt grass and
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Black rush together make up about 25 percent of the total cover (see Table 6).
Table 6. Percentage of plant species in the salt marsh region of Barataria Basin.
Spartina alterniflora (Oystergrass) Juncus romerianus (Black rush) Distichlis spicata (Salt grass) Spartina patens (Wire grass)
62.79 14.90 10.05
7.77
Source: R. H. Chabreck. 1972. Vegetation~ water, and soil characteristics of the Louisiana coastal region. Louisiana State University~ Agr. Exp. Sta. Bull. No. 664.
The highest production (growth) rate of Oyster grass occurs during late spring~ but the highest live biomass does not accumulate until September. The grass produces seeds in the fall~ then the upper (above-ground) parts die, and low water levels in the winter allow much of the dead grass to remain on the marsh. During the spring, as water level increases, much of the partly decomposed detritus is vJashed from the ,vetland into the estuaries. The spring salt marsh production peak seems to be related to the high average water level. which decreases after spring. Light could also be partially limiting to production late in the summer because Oyster grass belongs to a category of plants whose ability to photosynthesize increases with increasing solar radiation, even light levels beyond those at which most plants can respond. Therefore, at peak biomass some self-shading undoubtedly occurs. Some production by ina occurs year-round, since of plant remain alive in Louisiana during the winter.
Other important primary producers in the salt marsh include an epiphytic community that lives on the lower portions of Spartina stems and benthic algae (mostly diatoms), which inhabit creek banks and exposed sediments such as mud flats, as well as the areas between Spartina stems. These two groups are probably most sig-
nificant during winter and early spring before Spartina becomes denseo
Total annual salt marsh wetland production has been conservatively estimated for the
at 0.2 lb/ft2 the same estirl1ate arrived at for each of the other wetland types. This estimate does not take into account, however, the unknown proportion of plant production exported into the salt marsh estuaries by tidal flushing. The effect of "free" work done by water movement, in the form of stirring, nutrient supply, oxygenation, etc., is probably greatest in the salt marsh that is most affected by both normal and storm tides than any other wetland units. Published estimates of salt marsh production have exceeded 0.6 lb/ft2 ; th~ highest values usually apply to streamside grass where the edge effect enhances growth, and thus the salt marsh system again follows the general rule that plant production is highest at the edge of water bodies and decreases inland.
Two "side effects" of Spartina growth that seem to be of great functional importance to the marsh community are related to the extensive root systems produced by the plant. These roots impart a great deal of erosion resistance to the surface of the sediment. They also act as a nutrient "pump" to extract phosphorus from the anaerobic layers beneath the surface and transport it into the above-ground portions of the plant. Much of this phosphorus is then released into the surrounding waters when the marsh is inundated.
Primary Consumers The major groups of primary consumers in
salt marsh wetland (both detritivores and herbi~ vores) include bacteria and fungi, meiofauna, snails, fiddler crabs, polychaetes, mussels, insects, birds, and mammals. Of these forms, only insects such as grasshoppers can be considered primarily as grazers. It has been estimated that insects account for the removal of about 4 percent of the net primary production in salt marshes in Georgia (Teal 1962), and there is no evidence to indicate that either more or less insect grazing occurs in Louisiana salt marshes. Of the remaining primary consumers, most ingest a
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combination of detritus and epiphytic or benthic algae. The density of animals in salt marsh wetland is not uniform but is related to distance from a water body (most biomass occurs about 10 feet from an estuary). Thus the edge effect is reflected in salt marsh flora and fauna just as it is in the other wetland systems. Total mean biomass of primary consumers in the salt marsh is estimated at about 0.003 lb/ft2 at the edge of an estuary, increasing to a maximum of about 0.008 lb/ft2 , 10 feet inland, and then gradually declining further inland to about 0.001 lb/ft 2 (Day et al. 1973).
Fiddler crabs are one of the major components of the primary consumer community. These burrowing animals play an important role in turning over marsh sediments, exposing them to oxygenated water, and releasing nutrients from subsediments. Fiddler crabs feed by ingesting sediment particles, digesting organic material, and egesting unassimilated material. These crabs are an extremely important node in the salt marsh food web since a wide variety of animals including finfish, birds, and mammals use them as a major food source.
Marsh snails are the only primary consumers in the salt marsh that seem relatively unaffected. by the edge effect in that they are more uniformly distributed throughout the marsh than other animals. These snails live on the stems of Spartina and graze on the epiphytic algal community found there. Horse mussels are found throughout the salt marsh, living half buried in the sediment. They ingest food filtered from the water-flooded wetland, and they seem to be extremely important in returning phosphorus to the water and sediments after releasing it from ingested food.
Bacterial biomass in salt marsh sediments varies with the amount of organic matter, but in general the highest bacterial populations occur at the edge of water bodies. There seem to be fe,,,er bacteria in salt marsh sediments near the Gulf than in more inland areas. Of the total microbial flora in salt marsh sediments in the Barataria Bay area, about I percent were recently found to have the ability to break down cellulose. Species diversity of salt marsh bacteria is lower than in the fresh marsh areas.
Meiofauna and small macrobenthic forms that
are important primary consumers in salt marsh sediments include such groups as copepods, amphipods, • mites, insect larvae and nematodes. Feeding habits of the latter group are not clearcut, since some nematodes feed on protozoa and some are strictly detritivores. The organic material ingested by nematodes is un~ doubtedly significant, since these minute animals are so numerous, occurring in densities expressed in six figures in one square foot of marsh surface. Total annual meiofaunal ingestion in the salt marshes in the study area has been calculated at about 0.02 Ib/ft2 (compared to about 0.04 Ib/ft2 for the important macrofaunal forms discussed previously).
Carnivores Predatory species using the saltmarsh wet
land as feeding grounds include the same general forms and often the same species that are found " in brackish marshes. Insects, spiders,birds, and mammals are all included in the predator community. Reptiles, however, are relatively scarce in the salt marsh. The Gulf salt marsh" snake occurs there, and alligators may use the salt marsh occasionally, but otherwise reptiles are not represented.
Among the bird groups, wading birds are preeminent in the salt marsh, although probably more of their prey are caught at the edge of water bodies than in the marsh proper. The edge effect discussed previously acts as a natural concentrator of fauna to give wading birds a distinct advantage over animals whose prey are more randomly distributed. These long-legged birds can stand in one spot and feed efficiently, with little energy expended for searching or chasing prey. Probably an enormous amount of food in the form of animal protein is removed from the marsh daily by wading birds. During breeding season, wading birds concentrate in heronries on marsh islands from which members of mating pairs alternate in feeding forays. Growing birds require proportionally more food than mature birds. Large quantities of bird droppings fall to the sediment beneath the nesting sites and the resulting nutrient input to the snrronnd-
vlater shm-m to result
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in an unusually high density of phytoplankton. zooplankton, and probably fish. The same high concentration of nutrients from bird droppings occurs in roosting areas. Wading birds migrate daily between feeding and roosting areas; e.g., ibises are known to travel up to 50 miles for feeding. However, the pattern and effect of this migration remains to be worked out. Generally roosting occurs in elevated areas such as in mangroves, chenier areas, or levees.
Rails represent another predatory bird group that feeds primarily on crustacea. Shore birds such as sandpipers and plovers also feed at the marsh edge, especially in areas close to the Gulf.
Mammal predation in the salt marsh is exemplified by the raccoon, which feeds on practically anything including fiddler crabs, snails, rail eggs, and even some plant roots. No good estimates of mammal densities in the salt marsh are available; however, Day et ale (1973) lists raccoons as occurring at a density of 0.025/acre (see Survey of Coastal Organisms.)
Water Bodies IEstuaries)
Interaction between wetland and water bodies is more pronounced in the salt marsh than in any other environmental unit. The higher proportion of water to wetland and the higher frequency of flooding of the wetland by estuarine waters in salt marshes tend to make the distinction between these two components of the marsh/estuarine system somewhat meaningless, Estuaries in the salt marsh system include bays and lakes as well as tidal rivers, bayous, creeks, and even arti~ ficial canals, although these man-made canals do not always function in exactly the same manner as do natural water bodies, Han~Iiiade canal::> a:r:-e
rather than and are often lined with spoil banks higher than natural levees; thus they are in their with surrounding wetland,
Primary Production The estuarine portion of the saltmarsh unit.
especially the inshore ~l7aters of Barataria Bay,
is shallow and turbid with muddy substrate and is unfavorable for macrophytic species (large aquatic plants). During the winter, however, some local areas such as small ponds and bayou edges become shallow and clear restricted numbers of these Most pro~
duction in areas results from phytoplank~ ton, which is an extremely variable group both seasonally and in different estuarine areas. The salt marshes contain probably the least hetero~ trophic water bodies of all the wetland systems examined. This means that water bodies in the salt marsh zone more nearly than any other unit produce as much organic matter as is consumed there. One typical small lake (45 acres) examined near Barataria Bay was net producing during the summer and net consuming (heterotrophic) during the winter, presumably because of the seasonal nature of marsh grass input to the lake (Day et al. 1973).
Water bodies in the salt marsh unit are about one-half as productive as wetland proper (on an area basis), but the protein-rich algal production may be more usable in its original form than the cellulose-rich marsh grass.
Most numerous of the large phytoplankton types are diatoms, coccoid blue-greens, and coccoid green algae; however, perhaps the most important primary producers are the extremely small (nannoplankton and ultraplankton) algal cells that divide rapidly and account for about 90 percent of primary production in open oceans.
Primary Consumption Detritivores. As in each other unit dis
cussed previously, water bodies in the salt marsh are heterotrophic during most of the year and receive an energy "subsidy" from the salt marsh wetland and upstream marshes in the form of detritus. The edge effect applies to estuaries as well as to wetland proper in that the largest concentration of organisms occurs at or near the marsh water interface where detritus often accumulates. Samples of bottom sediment and detritivores taken from the edge of a lake or bayou in the salt marsh typically teem with a diverse group of detritivores, while the same kind of sampling in the center of the lake or
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bayou often yields nothing but nematodes. Herbivorous nekton. The salt marsh est
uaries are perhaps best known as nursery ground areas in that immature nekton migrate into the inshore areas during their peak growth period when their food requirements are greatest. It has been noted that the annual immigration of many of these groups occurs in spring, coinciding with the time of peak phytoplankton production in the water bodies and maximum export of reworked detritus from the marshes. Much information has been gathered on immigration times of such commercially important species as penaeid shrimp (white, brown, and pink shrimp). Menhaden and mullet are major herbivorous finfish species that use the estuaries as nursery grounds. Menhaden growth is highest within Barataria Bay, but the fish are harvested mainly offshore (see separately
published reports on shrimp and menhaden in this series).
The above familiar primary consumers and numerous other noncommercial nektonic species feed on a combination of detritus, phytoplankton, and some zooplankton.
Zooplankton as a group is composed of a loose assemblage of unrelated animals including small crustacea, as in the less saline wetland systems, decapod larvae such as blue crab larvae, and large planktonic forms that are actually carnivores, such as comb jellies (ctenophores) and sea nettles. Ctenophores often are considered a major factor in the control of small zooplankton.
Zooplankton in estuaries are clearly dominated by the copepod Acartia tonsa which is the only form that maintains a large resident population year round. Spring and fall peaks of zooplankton are characteristic, but this pattern is not clear cut since different species become abundant at different times.
Predation in Salt Marsh Estuaries Wading birds and their role of predation at
e margins have been mentioned above. The other large bird predators in the estuaries include fishing birds (such as white and brown pelicans, skimmers, gulls, terns), diving ducks (such as scaup and mergansers), and now, rarely, ospreys. Feeding habits of these birds vary;
e.g., white pelicans feed close inshore, while brown pelicans fish in open ,vater, the latter feeding chiefly on menhaden and mulleL A small colony of brown pelicans has apparently been
reestablished in coastal Louisiana" The entire population congregates in one rookery to breed in the spring. The rookery is on Queen Bess Island in Barataria Bay.
A prominent carnivore in salt lllarsh estuaries and offshore areas is the bottlenosed dolphin, a mammal whose pursuit of fish leads far up the coastal waterbodies, at least to the northern limit of the salt marsh system.
The most familiar carnivores in the saltmarsh estuaries are such sport fish as Spotted sea trout, but many smaller finfish are also important predators including Mosquito fish, Killifish, Sea catfish, and the extremely abundant silversides and anchovies. Anchovies have been described as the most abundant finfish in inshore waters.
Organisms of Special Interest or Economic Significance to Man
Pest insects: Salt marsh mosquitoes are the most predominant marsh mosquitoes in southeastern United States. Biting midges (nosee-urns) are also quite abundant at times near salt marshes.
Fur animals: Trapping of mammals for fur is somewhat less important in salt marshes than in less saline marsh areas because fur quality is generally lower here. Some raccoons, muskrats, and mink.are harvested, however.
Sport fish: In salt marsh estuaries sport fishing is aimed at such important game and food fish as red drum (red fish), spotted sea trout (speckled trout), sand trout, sheep shead , croaker, flounder, and pin fish.
Blue crabs: The blue crab ranks third in total poundage of all commercial fisheries in Louisiana, and fourth in dollar value, after shrimp, menhaden, and oysters. Blue crabs are very abundant in salt marsh estuaries in the shows the
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per acre yield of blue crabs of any Louisiana coastal area).
Menhaden: Menhaden is an important commercial fish and is more concentrated within salt marsh estuaries than offshore but is harvested only offshore. The menhaden fishery is the largest in total poundage of any Louisiana fishery and second in total dollar value (Stone 1976).
Penaeid shrimp: Brown, white, and pink shrimp are harvested both offshore and within the salt marsh estuaries and bays. The shrimp harvest is the most valuable fishery in Louisiana, accounting for about 60 percent of the total dollar value. The Barataria and Terrebonne estuaries, which encompass the study area, are the most productive shrimping areas of the state (Condrey, in preparation) .
Oyster: The oyster fishery is economically very important in coastal Louisiana (third in dollar value). The locations of major oyster leases in the Barataria Basin have shown a net movement inland in past decades due to salinity intrusion in the lower basin areas (Van Sickle et al. 1976). Oysters and other bivalves are often used as indicators of heavy metal pollution since they tend to concentrate in their tissues amounts of heavy metals which are proportional to those found in their environment. Unpublished data from Dr. Clara Ho (Louisiana State University Center for Wetland Resources, Baton Rouge, La.) give heavy metal concentrations in oysters collected from areas just east of the Mississippi River. The follow"ing concentrations were found:
Zinc 200~281 mg/IOO g dry wt Iron 61-68 mg/IOO g dry wt Copper l2~·22 mg/lOO g dry wt Mercury 15-138 ppb wet wt
These levels are all below FDA allowable levels in oyster meat. Levels indicate that selective absorption of zinc occurs since in the sediments: Fe»Mn>Zn>Cu; whereas, in the oyster: Zn»Fe>Cu>Mn.
Brown pelican: The entire Louisiana population of introduced brown has established a nesting site inside Barataria Bay on a small island (Queen Bess Island),
white can be observed in salt marsh area" ThpRP h:i.rrlR Are considered rare enough to be placed on the blue list.
Reddish egret: This wading bird is becoming rare and is now on the blue list, A few can usually be seen in salt marsh and beach areas.
Other rare birds: The following birds are all becoming rare and are on the blue list. They are not limited to the salt marsh study area but have been seen in various wetland portions of the entire basin: Osprey Black vulture, Loggerhead shrike, and Peregrine falcon.
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f
The combined net organic production exported from all four wetland units is eventually transported to the Gulf via the water bodies that drain the entire coastal ecosystem. This integrated result of wetland primary production consists of a complex of organic matter ranging from relatively undegraded plant fibers to high quality animal protein in the form of nekton, which, having entered the estuaries to take advantage of concentrated food sources, emigrate back to open waters taking their estuary-enhanced biomass with them. Export of wetland production in the form of such highly processed energy represents the culmination of a complex series of natural processes, all carried out at no cost to man, but from which man reaps the final product.
The physical characteristics of the areas offshore from the Barataria Basin are atypical of most marine systems in that they are strongly influenced by the Mississippi River. Every day 361 billion gallons (10 million m3) of fresh water and tons of dissolved and suspended matter are dumped into the Gulf roughly 50 miles to the east of the waters off the Barataria estuary.
Rather than mixing immediately, however, the fresh water forms a huge plume, which, being less dense than Gulf waters, floats on the surface and moves in variable directions, depending on winds, tidal currents, and oceanic currents. Sometimes the plume forms a giant gyre that sweeps in a clockwise direction and directly impinges on the Barataria offshore area. Surface salinities at Barataria Pass then drop to low brackish levels. Surface water salinity in the Barataria offshore area varied from 9.3 to 31.8 ppt during a study conducted in 1973-74. Mid~depth and bottom water showed less change, however. When the difference between surface and bottom salinity was greatest, heavy metal concentrations in the water seemed greatest but heAVY metals never exceeded normal concentrations.
It has been suggested that the richness of fisheries in marine waters off Barataria and Terrebonne Bays (exceeding any other area of the state) are at least partially the result of the entrapment of offshore marine animals prevented from eastward migration by the freshwater discharge of the Mississippi, and by the modern
delta, which extends to the edge of the continental slope, resulting in an extremely narrm.;r and restrictive shelf area adjacent to the delta.
A phenomenon that is possibly also related to the Miss River has been noted in the waters offshore from Barataria Bay. This is a large mass of oxygen-free ,.;rater of undetermined spatial and temporal distribution. Similar smaller zones of oxygen deficit have periodically been noted in offshore areas adjacent to Mississippi Sound. These occurrences have been called "jubilees," and they are often correlated with periods of high freshwater discharge from land and high temperature. The name refers to the
mass emigration of decapod crustacea and fish toward shallower water in an effort to flee the oxygen deficient area. The mechanisms that cause the oxygen deficit are not yet understood, although they are possibly related to the density gradient set up by the fresh water plume of the Mississippi River. Relatively warm fresh water floating on top of the colder more saline bottom water discourages mixing and effectively isolates the bottom layer. High levels of organic matter in bottom sediments, which have been found in the offshore area, indicate rapid uptake of dissolved oxygen from the 1"rater covering these sediments. Thus the bottom water could become oxygen deficient. A large area of bottom waters appears to be affected, perhaps 1,000 square miles or more. In the lowest 2 or 3 meters of water sometimes no oxygen can be detected. If winds and tidal currents displace the surface waters in an offshore direction, the oxygen deficient bottom water can be displaced into shallower water, resulting in jubilees and fish kills. A fish kill in the area during July 1973 appears to have resulted from such a phenomenon.
Whether or not the development of large areas of deoxyngenated bottom water in the area offshore from Barataria Basin is becoming more frequent is not known. The chemical characteristic of the offshore environmental unit is affected by the onshore units in terms of export of organic material from the estuaries to the Gulf (outwelling). They are also affected as noted above by the Mississippi River drainage. Nearshore waters are generally higher in nutrients
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and trace elements than waters farther offshore. A recent study has shown a distinct gradient of total organic matter (suspended and dissolved) in water along a study transect beginning inside Barataria Bay and extending into the nearshore waters of the Gulf. However, examination of the more offshore portion of the study area has revealed no clear trends or gradients of either inorganic nutrients or organic material in Gulf waters.
Primary Production No direct measurements of primary production
have been made in the offshore study area; however, extrapolations from other similar areas are feasible based on kinds of autotrophs present and also on estimates of the density of primary and secondary consumers supported partially by these autotrophs and partially by energy exported from wetland systems.
The flora of the Gulf is made up almost entirely of planktonic species, with macrophytes being limited to man-made structures such as oil production platforms. About 35 species have been enumerated in past studies and diatoms and dinoflagellates are dominant. The highest number of species and the greatest density of algal cells have been found at the nearshore sampling locations"
As in the saline inshore vmters, it is likely that the most important primary producers in the open Gulf are nannoplankton and ultra~ plankton, which are too small to be retained by a normal plankton net and which are believed to account for 90 percent of primary production in open ocean waters.
Phytoplankton require sunlight that pene~ trates deep water bodies to an extent highly
on the of the surface l>mters. Sunlight energy required for primcl1".y pronurtjoTl is available only in the upper or zone," which in the study area is fairly shallow.
Primary Consumption Zooplankton comprise a major link between
primary production and higher trophic levels in the offshore Gulf waters. The dominant copepod, Acartia tonsa, has been found in peak densities exceeding 57/ft 3 in June. This species and many
other zooplanktonic crustacea seem capable of ting both and detritus i~
cles. Total in the Barataria offshore area is highest the more nearshore locations, concentration numerous during numerous during the winter.
Of the finfish such as mullet and menhaden that represent major detritivores in the offshore and estuarine systems, there seems to be a trend of trophic change paralleling growth and development of the fish. Many fish that seem to feed rather indiscriminantly as adults and are considered filter feeders are more selective as larval and young fish and actually search out individual food items such as small zooplankton forms like the copepod Acartia tonsa. This trend of changing diet with size seems to apply to anchovies, croakers, silversides, and threadfins, as well as to mullet and menhaden. Menhaden represent the largest portion (by weight) of total fisheries harvest in Louisiana and comprise
a major portion of the total primary consumer biomass in offshore, nearshore, and estuarine waters. There is some evidence that present yields of menhaden in the waters off Barataria Bay are near the maximum that can be sustained. Peak concentration of menhaden occurs off the Barataria estuary.
The passes connecting the salt marsh estuaries of Barataria Basin with the nearshore waters beyond the coastline are major thoroughfares for a variety of species in various stages of their life cycles. Most nektonic species (shrimp, snappers, groupers, drum, menhaden) spawn offshore, the larval stages being carried inshore into estuarine waters where they grow rapidly, and then the juvenile organisms begin moving back out to sea to complete their life cycle. Speckled trout show a different life history in that they generally spawn in inshore waters. The major movements through these vital passes are inshore during the spring and seaward during fall. Menhaden are classed as unusually "early" fish, in that they begin moving inshore in winter and are gone from the est~ uaries by midsummer.
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During a past study detritivorous (as well as carnivorous) nekton seemed to be more abundant in shallower (nearshore) and deeper (offshore) locations than in the intermediate area associated with low oxygen bottom/water. Total nekton seemed to decrease from east to west. Among the detritivorous finfish captured during sampling, the Bay anchovy was most abundant at three out of four locations.
Shrimp, including the commercially important Sea bob, Brown shrimp, and White shrimp, comprise only about 2 percent by weight of nekton samples. These species are, however, of great economic value to the people residing in and around the Barataria Basin. Shrimp ecology is discussed in some detail in a separate publication in this series.
Often the specific forms making up the benthic community are determined by the bottom sediment into which many of them burrow. Benthic macrofauna that burrow and feed on detritus in the sediment or filter it from the water as it settles include mollusks such as clams, many species of polychaete worms, and echinoderms such as sand dollars and sea cucumbers. Another group of benthic organisms resides on the upper surface of the bottom or on something hard such as a shell, and this group characteristically filters particles from the water. These epibenthic forms include minute bryozoa. sponges, barnacles, some polychaetes, and mussels. Motile forms such as mud crabs, mud snails, and amphipods crawl over the bottom and scrape detritus from the surface.
The rich benthic community (which in turn is the source of food for bottom feeding nekton such as flounders) is thus dependent on a continual rain of detritus from the upper euphotic zone of the offshore waters. A community of much smaller benthic meiofauna or interstitial animals such as npmAtorh~s} smAll (,TllstA(,pa ann ciliate protozoa also resides in the rich sediments on the bottom of the Barataria offshore zone and, together with the microbial conmmnity, makes up another maj or portion of the benthic detritivore complement. Insects are conspicuous by their total absence from this and most other marine communities.
During a recent study of the benthic community in the offshore study area, samples contained an average of over 84 macro faunal organisms per
square foot although density of this community decreased sharply beyond 50 foot depth~ The
locations showed only one fourth the number of animals found closer to shore.
\Vere dominant and maximum density was found in June.
Carnivores Predators in the offshore study area are
comprised essentially of the same groups (if not identical species) that are found in salt marsh estuaries, except fOl~ those relatively rare forms avoiding shallow turbid areas because of their high oxygen requirements. These are the large, fast-swimming forms such as Blue marlin, which are prized as game fish by deep sea fishermen. Commercially harvested carnivorous finfish taken in or near the study area include Spotted seatrout, Red snapper, King fish, Black drum, Red drum, Flounder, and a number of lesser species. Fishing from oil well platforms in the study area often yields Red snapper, Amberjack, Bluefish, and Cobia.
Some predacious invertebrates are restricted to marine salinities, including echinoderms such as starfish and some boring snails. Both of these groups feed largely on bivalves.
Predatory birds that feed offshore include gulls such as the Laughing gull, Ring billed gull, and Herring gull; several species of terns; Man-o-war or frigate birds; and Brown pelicans.
Often the latter birds can be seen perched on oil well platforms.
Reptiles are normally not found in the northern Gulf of Mexico, with the exception of the Green sea turtles that are occasionally drowned in shrimpers' nets. Man represents the· most significant predator in the offshore area; and a major source of the energy required to support the food web from which man harvests his prey is the coastal wetland system, which annually exports a portion of its net production into offshore marine waters.
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Organisms of Special Interest or Economic Significance to Man
.~
Penaeid shrimp: Brown, white and pink shrimp, and the small form known as the Sea bob are harvested mainly in the Gulf and bay waters. These shrimp represent the most valuable fishery in Louisiana in terms of dollar value.
Green sea turtle: Although the Green sea turtle does not maintain nesting grounds on the north shores of the Gulf of Mexico, these large reptiles occur in offshore waters of the study area and are sometimes drowned in shrimpers' nets. They are considered rare and endangered.
Brown pelican: The Brown pelican, a fishing bird, obtains its major food item (menhaden) mostly in the offshore area.
Lesser Scaup: As a common waterfowl the Lesser Scaup feeds offshore and is an important game bird (in southeastern Louisiana) in the salt marsh area.
Menhaden: The maximum harvest of menhaden in one year in Louisiana was about one billion pounds, but the average catch per unit effort has been decreasing, indicating that the total net production is being harvested. Essentially the entire commercial harvest of this fish in Louisiana waters occurs off Barataria and Terrebonne Bays (1,070 lbs per acre) (Stone 1976).
Other commercial or sport finfish: Spotted sea trout (speckled trout), Red snapper, King fish, Black drum, Red drum, Flounder, and a number of lesser species are all caught on a commercial basis offshore in the Barataria Basin.
aches
The beach areas of Barataria Basin represent an extremely small area in proportion to the wetland systems of the basin. These areas are subj ect to varying degrees of \Vave energy and are
to their to defend more vulnerable marsh areas from the erod AffAC'ts of waves, tides, and storm surges. The sands forming these beaches portray a net westerly drift, and in some areas, such as that around Bay Champagne near the mouth of Bayou Lafourche, rapid erosion and a dearth of available sand produces a retreating beach with practically no dunes.
In most beaches there is a community of minute detritivores and predators living totally unobserved to the casual observer in the lower forebeach in the interstices between sand grains~ This community of microbes and small meiofauna (predominantly crustacea) is supported by organic carbon filtering onto sand grains from the marine water that soaks into the sand. Thus a system is set up somewhat comparable to a trickle filter used in the treatment of sewage. Stirring by the surf ensures adequate oxygen supply for respiration, and the community is quite active. Shore birds such as plovers, sandpipers, and willets represent a major beneficiary through predation o~ the community of animals residing on the beaches. Plovers are known to feed mainly on flea hoppers rather than meiofauna. Small fish feed both on meiofauna and the larger benthic macrofauna, such as butterfly coquinas and other bivalves.
Beach Vegetation
Sauer (1967) states that "the dominant coastal species are all evergreen perennials, showing remarkably little seasonal change in aspect." Many are xerophytic and adapted to natural disturbance and can thus persist in areas heavily occupied by man.
Brown (1951, unpublished manuscript) noted plants along a transect across Grand Isle near the old LSD Marine Laboratory.
Along the lee~.,ard edge of the island is a band of 1m-1 of
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(Spartina alterniflora), Salt grass (Distichlis spicata), Black rush (Juncus roemerianus), Blackmangrove (Avicennia nitida), Glasswort (Salicornia sp.), Batis (Bat is maritima), and Widgeongrass (Ruppia sp.).
Approaching the higher ground on the island is a narrow zone of high marsh (transition marsh). Plants in this zone include Marsh-elder (Iva frustescens), Saltmarsh fimbristylis (Fimbristylis castanea), Three-cornered grass (Scirpus olneyi), Leafy three-square (Scirpus robustus), Wiregrass (Spartina patens), and Sea-oxeye (Borrichia frutescens).
On the highest ground down the center of the island is a wooded area, with trees including Live oak (Quercus virginiana), Hackberry (Celtis laevigata), Hercules-club (Zanthoxylum clavaherculis)~ Wax myrtle (Myrica cerifera), and St. Augustine grass (Stenotophrum secundatum). The wooded zone may be reduced or lacking on islands of lower elevation.
Toward the Gulf from the wooded area is a broad zone of meadow habitat. Plants encountered along the transect here included: Beard grass (Andropogon sp.), Finger grass (Chloris petraea), Saltmarsh fimbristylis, Frogbit (Lippia lanceolata), Erigeron repens, Pennywort (Hydrocotyle bonariensis), Black rush, Three-cornered grass, Softstem bulrush (Scirpus validus), Wjdgeongrass (Ruppia maritima), Sandspur (Cenchrus sp.), Morning glory (Ipomoea stolonifera), Heterotheca subaxilaris, Sabbatia (Sabbatia sp.), Wiregrass, Dog tooth grass (Panicum repens), and Bermuda grass (~odon dactylon) .
The dune habitat is the closest to the Gulf to support rooted vegetation. Plants here include Dog tooth grass (Panicum repens), Beach morning glory (Ipomoea pes~caprae), Morlling glory, Frogbit, Heterotheca, Evening primrose (Oenothera), Sandspur, and Sea rocket (Cakile).
Sauer (1967) classified beach plants according to their origins and distributions. Although Sauer studied beach plants along the Mexican Gulf Coast, some species range through the northern Gulf Coast as well.
Four of the species found on Grand Isle by Brown (Pennywort, Morning glory, Blackmangrove, and Beach morning glory) are classified by Sauer (1967) as having natural transoceanic ranges.
They are primarily coastal species and occur on all Gulf shores in appropriate habitat. The Beach morning glory is the most conspicuous species in the outpost zone on a worldwide basis.
and Sea rocket are coastal species ,-,hose ranges are restricted to the New World. Scattered individuals of Sea~ oxeye may occur in inland salt marshes. Two species of Sea rocket have been recorded from Gulf shorelines, one species being restricted to the southern Gulf and the other ranging to the northern Gulf coast as well.
Sandspur, Bermuda grass, and Heterotheca are primarily inland plants that reach the margins of their distributions in seashore habitats. Sand~
spur occurs on both the North American mainland and in the ,.;rest Indies> 'while Heterotheca is restricted to the mainland. Bermuda grass is a recent introduction from the Old World.
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70
tal r
Natural levees, which form adjacent to bayous in all wetland systems as a result of periodic flooding and sediment deposition, are extremely important as ecological reservoirs of species diversity. These low relief features in wetland areas provide for the establishment of many "high ground" plant species that add more to the system in terms of spatial diversity (habitats) than to the production of organic carbon. The provision of stable areas for nesting sites, etc. is perhaps most important to the terrestrial animals in the system. Reptiles, for example are often associated with natural levees and spoil banks.
The precise elevation of natural levees is strictly controlled by the cyclic changes in water level and represents a "self-designing" feature of a wetland system. Relative elevation between land and water has previously been described as extremely critical to the periodic flooding of wetland, which is essential to the maintenance of high production in these systems.
Man-made relief features in wetland areas often take the form of spoil banks resulting from dredging of canals. Piles of spoil material that line the banks of water bodies differ from natural levees in elevation and orientation. Rather than being regulated by long~term natural processes, they are often on a and in a manner that can create severe impairment to water movement,
Spoil banks in the Barataria Basin quickly become populated by a plant community and eventually serve as feeding and nesting sites for many animals. With time much of the organic matter in the dredged material oxidizes, some of the spoil is w'ashed away by rain, and the elevation eventually decreases, sometimes almost to the original marsh level, By this time, however, much adjacent wetland can be des because the death of marsh grass often results in oxidation of underlying sediments that lowers the level of the entire area, and less water bodies form in the of ~lTetland, Vegetation succession on spoil banks will be described in detail later.
Palmisano (1970) characterizes the vegetation on spoil banks and natural levees in coastal marshes (Table 7) and for large crevasses and
natural levees in the deltaic plain (Table 8). Species composition undoubtedly varies across the coast and within each hydrologic unit, so this list must be considered tentative for the Bara~ taria Basino
Table 7. Plant species composition of spoil banks and natural levees in coastal Louisiana.
Baccharis sp. (Groundsel tree) Iva frutescens (Marsh elder) ~odon dactylon (Bermuda grass) Spartina patens (Marshhay cordgrass) Pistichlis spicata (Saltgrass) Phragmites communis (Roseau cane) Rubus sp. (Blackberry) Trees (when present)
Salix nigra (Black willow) Sapium sebiferum (Tallow tree)
Source: A. W. Palmisano. 1970. Plant communitysoil relationships in Louisiana coastal marshes. Ph.D. diss. Louisiana State University, Baton Rouge, La.
Table 8. Plant species composition of large crevasses and natural levees in the Louisiana deltaic plain.
Taxodium distichum (Cypress) Nyssa aquatica (Tupelo gum) Acer drummondii (Swamp maple) ~alanthus occidentalis (Buttonbush) Salix nigra (Black willow) Fraxinus pennsylvanica (Green ash) Gleditsia triacanthos (Honey-locust)
Source: A. W. Palmisano. 1970. Plant community~ soil relationships in Louisiana coastal marshes. Ph.D, diss. Louisiana State University, Baton Rouge, La.
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Tree species composition for chenier ridges (marsh-stranded beaches) has also been given by Palmisano (1970). These ridges provide islands of terrestrial habitat in the coastal marshes. Live oak (Quercus virginiana) is often the most frequent tree species (Table 9).
Table 9. Tree species composition of cheniers in coastal Louisiana.
Quercus virglnlana (Live oak) Celtis laevigata (Hackberry) Ulmus americana (American elm) Acer drummondii (Swamp maple) ~dium distichum (Cypress) Gleditsia triacanthos (Honey-locust) Zanthoxylum clava-herculis (Hercules-club) Diospyros virginiana (Persimmon) Quercus nigra (Water oak)
Source: A. W. Palmisano. 1970. Plant communitysoil relationships in Louisiana coastal marshes. Ph.D. diss. Louisiana State University, Baton Rouge, La.
Succession on poil nks
Monte (unpublished MS) conducted transects of spoil banks ranging in age from 1 to 30 years old in freshwater swamp, fresh marsh, brackish marsh, and saline marsh. A transect was also run in a bottomland hardwood forest habitat for comparlson.
Mean cover values were determined for all species and from these were calculated species dominance, zonation, life forms, and diversity. Diversity was calculated by taking the ratio of observed diversity to the maximum diversity possible with the same number of species. Patterns of succession in the different environments were studied using the formulas of Bray and Curtis (1957) and Community Ordination Analysis (Cox 1967). These calculations facilitated comparison of spoil bank vegetation communities both within and between habitats.
Saline Marsh
Monte found that, in the first year, a spoil bank in the saline marsh was dominated by Oyster grass (Spartina alterniflora), with almost 50 percent of the spoil bank being bare ground. After 4 to 5 years, Wiregrass (Spartina patens) had become the dominant species, and there were scattered shrubs of Baccharis (Baccharis halmifolia). By the tenth year, shrubs of Baccharis and Marsh elder (Iva frutescens) had reached a height of seven feet and had begun to shade out the wiregrass, a process that was virtually complete by the twentieth year. Thre were occasional Black mangroves (Avicennia germinans), especially along the coast. This species prefers higher, drier habitats (Thom 1967).
In the thirtieth year, trees dominated spoil banks in the saline marsh, the major species being Toothache tree (Zanthoxylum clava-herculis) and Hackberry (Celtis laevigata). The dominant shrub in the understory was Elderberry (Sambucus anadensis).
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711
Brackish Marsh
The first year spoil bank studied in the brackish marsh by Monte (unpublished MS) had been invaded by Wiregrass and Baccharis but there were also large areas of bare ground. In the second and third year, Wiregrass and Saltgrass (Distichlis spicata) together covered 70 percent of the spoil bank and there were scattered shrubs of Baccharis. As the Baccharis increased in size, the grasses were shaded out and by the tenth year were virtually gone. Marsh elder and Goldenrod (Solidago sp.) were found growing along the edge of the ten-year-old spoil bank. A few scattered Toothache trees had appeared by the tenth year.
After fifteen and twenty years, the shrub layer was well developed and included Baccharis, Wax myrtle (Myrica cerifera) and Elderberry with scattered Toothache trees and Elm (Ulmus americana). The herb layer consisted mostly of Goldenrod and Melonette vine (Melothria pendula). On a twenty-five-year-old bank, Elderberry was the dominant shrub and the Melonette vine had increased in abundance.
On the thirty-year-old spoil bank the tree canopy was about thirty feet high and consisted of Hackberry, Black willow (Salix nigra), Toothache tree, and Chinaberry (Melia azedarach). The twelve foot high shrub layer was dominated by Elderberry. Other important understory plants included Cow-itch (Cissus incisa) and Bloodberry CRi vina humilis).
Fre arsh
Small Baccharis shrubs and a mixture of herbs had invaded a one-year-old spoil bank in fresh marsh (Monte, unpublished MS). Water hyssop (Bacopa monnieri • Flatsedge (Cyperus sp. ) , taria 1ancifo1ia). and Smartweed (Polygonum puncta tum) wer~found growing along the edge of the spoil bank, while Goldenrod, Aster (Aster sp.), Yankeeweed (Eupatorium capillifolium. Saltmarsh mallow (Koste-1etzkya virginica), and Hemp sesbania (Sesbania macrocarpa) "were more abundant in higher e1e-
vations. also
Seedlings of Willow (Salix sp.) were the first year.
By the third year. the 1:<Jillows had grown to 10 to 12 feet and six~foot tall Baccharis was
By the fifth year the herbs had been shaded out,
After 15 years trees were becoming dominant. Twenty-foot high Willow and Swamp maple (Acer drummondii) were present, and the ten~ to twelve~ foot high shrub layer consisted of Baccharis, Elderberry, and White snakeroot (Eupatorium rugosum) .
Trees continued to increase in dominance until the thirtieth year, when the spoil bank was virtually covered with trees. Dominant trees were Hackberry and Willow, with Toothache trees and Chinese tallow (Sapium sebiferum) being scattered in the understory. Shrubs, vines, and herbs consisted of Boxelder (Acer negundo), Elderberry, Wax myrtle, Hackberry seedlings, Roughleaf dogwood (Cornus drummondii), Goldenrod, and Melonette.
Swamp
The swamp spoil banks sampled by Monte were more heterogeneous than those in marsh areas because of local disturbances of the vegetation by industrial and agricultural activities. These disturbances undoubtedly influenced the successional sequence inferred from the transects.
Herbs such as Giant ragweed (Ambrosia trifida), Goldenrod, and Yankeeweed dominated the
one-year-old spoil bank in the swamp habitat. Also present were shrubs such as White snakeroot and Baccharis, and small tree seedlings. Vines included Peppervine (Arupelopsis arborea), Deer pea (Vigna repens), and Coralbeads (Cocculus carolinus) .
The four-year-old spoil bank was covered with trees and vines reaching heights of 20 and 10 feet, respectively. Dominant trees included Willow, Cottonwood (Populus deltoides), and Swamp maple while the major vines were Dewberry (Rubus louisianus), Peppervine, Climbing hempweed (Mikania scandens , and Passion flower siflora ~-.-~~.~.~. shade~tolerant herbs as
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Smartweed and Lizard's tail (Saururus cernus) grew at ground level.
On older spoil banks trees continued to dominate and increase in size. The tree community succeeded from Willow-Cottonwood to MapleElm, to Hackberry-Water oak (Quercus nigra). Dominant shrubs on the older banks included Elderberry, Poison ivy (Rhus radicans), Wax myrtle, and Baccharis. Vines such as Dewberry, Peppervine, Cow-itch, and Rattan vine (Berchemia scandens) were also present.
Overview
The number of species of plants found on spoil banks generally decreased from fresh swamp to saline marsh, and the number of species tended to increase with age in each habitat.
The Shannon-Wiener diversity index showed an increase in diversity proceeding from saline marsh to fresh swamp. Diversity values increased with age on saline marsh spoil banks and showed a slight decrease with age in the fresh swamp. These values tended to converge for the four environments over time, ranging from 1.0 to 3.4 in the first year and from 2.6 to 3.3 for the thirtieth year.
Vegetation communities in the different environments were also compared by calculating dissimilarity values. These values tended to decrease through time, a further indication of convergence. Some of the species held in common among spoil banks in the different environments~~ especially Willow, Hackberry, and Elderberry-have been recognized as occurring in succession in bottomland hardwood forest.
Succession rates appeared to be greatest on fresh swamp banks where the tree stage was reached the fifth year and slowest in saline marsh, where the tree stage was not reached into the thirtieth year.
Finally, a transect through mature bottomland hardwood forest was compared with thirtyyear-old spoil bank communities in each wetland habitat. Calculation of similarity values showed 34 percent similarity to fresh swamp spoil banks,
18 percent to fresh marsh banks, 16 percent to brackish marsh banks, and 4 percent to saline marsh banks. This comparison further illustrated differences in rates of success ibn.
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ur y f t t ni
This section deals primarily with the distribution and abundance of selected animal groups within the Barataria Basin. It is by no means exhaustive and concentrates on animal groups that have received some attention from researchers.
Most groups are poorly studied. Very often the only information available for a species is its presence or absence in the basin. For others there are isolated observations of food habits, habitat relationships, or other aspects of life history.
Invertebrate Example IBlue Crab!
Jaworski (1972) gives an outline of the life history of the Blue crab (Callinectes sapidus). Females spawn in waters of relatively high salinity in the lower estuary and marine area during the warmer months. After hatching, this species passes through two larval stages (zoea and megalops) and is found primarily in marine areas and tidal inlets. After attaining the first true crab stage (46-84 days after hatching), they move into the lower and upper estuaries where they undergo 4-17 molts and attain a size of 6-100 millimeters in the first year. Part of the second year is spent in the upper estuary where they undergo 3-16 more molts, reaching sexual maturity at a carapace (shell) width of 125-200 millimeters. Mating takes place in relatively low salinity waters, after \l7hich females migrate to higher salinity areas and males remain in brackish areas or even migrate farther up rivers (Van Engel 1958). Figure 2 shows subhabitats used by blue crabs in the Barataria Basin.
As a species that uses most habitats in a given basin at some stage in its life cycle, the Blue crab populations are bound to be reduced by
Reduction in brackish ~ the
and matunltion. of blue crabs in the Bara
tar'ia estuary have declined since 1959 (Jaworski 1972). This decline (Fig. 3) has been particularly noticeable in the upper estuary, e.g., Lake Salvador. Most crab fishing is now centered in Barataria and Caminada bays. This decline has
,: Maturation Area
~ Winter Area
~ Spawning Area
Fig. 2. Model of the Blue Crab subhabitat in the Barataria estuary (after Jaworski 1972).
been attributed in the past to increased use of nonselective crab pots, which catch gravid females and thus presumably reduce the reproductive potential of populations. Blue crabs have extremely high reproductive rates, however, and reduction of breeding stock does not seem a likely cause of the decline. Jaworski (1972) presents evidence that an increase in the amount and kinds of pollution in the upper estuary may more likely be responsible for lowering of crab landings in this area.
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.. -0
6
5
5 .4 o a.
'0 3 .. " :¥ ~ 2
59 60 61 62 63
D Upper estuary, hard crabs
~ Lower estuory, hard crabs
~ Upper estuary, solt.shell crabs
64 65 66 67 68 69 Year
Fig. 3. Crab landings from the Barataria estuary, 1959-70. Lake Salvador and Utile Lake are included in the upper estuary, and
CaminacJa and Barataria bays comprise the lower estuary. Source: National Marine Fisheries Sel'{ice. 1959-1970. Landing Records: Louisiana Coastal Parishes, Form 2-164 SA&G; New Orleans, La , Fish and Wildlife Service, U.S. Dept. Commerce. After Jaworski 1972.
Fish
The fish of the Barataria Basin represent a diverse assemblage of species, and their high mobility coupled with their great variety of responses to environmental parameters makes detailed analysis of community structure diffi~ cult at this time. Fish species collected in the four major habitat types in the Louisiana Offshore Oil Port study (LOOP Report 1976) are given in Table 10. This tabulation represents a static view of fish distribution when in reality few, if any, of these species are restricted to a single habitat type. Seasonal movements of fish populations are quite widespread and as a result marine fish commonly penetrate inland to fn~shwater habitats and freshwater species sometimes occur in more saline water. The terms stenohaline (narrow salinity tolerance) and euryhaline (broad salinity tolerance) have not been rigorously defined and the distinction between the two is highly arbitrary (Gunter 1942). Whether fish species respond to salinity per se in their seasonal movements is not known. The lower reaches of freshwater streams may serve as
nursery areas for young of some marine species (Saul1974).
Day et al. (1973) reported the abundance of certain fish species in Caminada Bay during
and summer. Three the Clnr:.hovy (Anehoa ==.::=::::.::::.::::::::.'
patronus), and Spot
Table 10. Fish species collected in the four major habitat types in the Louisiana Offshore Oil Port study (LOOP Report).
Salt Marsh Bull shark (Carcharhinus leucas) Alligator gar~(L~pisosteus spatula) Bowfin (Arnia calva) Ladyfish~ops saurus) Shrimp eel (Ophichthus gomesi) Skipjack herring (Alosa chrysochloris) Gizzard shad (Dorosoma cepedianum) Atlantic thread herring (Opisthonema oglinum) Scaled sardine (Harengula pensacolae) Striped anchovy (Anchoa hepsetus) Dusky anchovy (Anchoa lyolepis) Inshore lizardfish (Synodus foetens) (Aphredoderus sayanus) Gulf toadfish (Opsanus beta) Atlantic midshipmann (P~hhythys porosissmus) Southern hake (Urophycis floridanus) Atlantic needlefish (Strongylura marina) Diamond killifish (Adinia xenica) Sheep shead minnow (Cyprinodon variegatus) Gulf killifish (Fundulus grandis) Longnose killifish (Fundulus similus) Rainwater killifish (Lucanis parva~ Mosquitofish (Gambrusia affinis) Least killifish (Heterandria formosa) Sailfin molly (Poecilia latipinna) Tidewater silverside (Menidia beryllina) Dusky pipefish (Syngnathus floridae) Chain pipefish (Syngnathus louisianae) Gulf pipefish (Syngnathus scovelli) Crevalle jack (Caranx hippos) Atlantic bumper (Chloroscembrus Leather jacket (Aligoplites ~-~-~~_, LookdOlvu (Selene vomer)
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Table 10. Continued.
Florida pompano (Trachinotus carolinus) Atlantic moonfish (Vomer setapinnis) Gray snapper (Lutjanus gris~us) Spotfin majarra (Eucinostomus argenteus) Silver jenny (Eucinostomus gula) Sheep shead (Archosargus probatacephalus) Pinfish (Lagodon rhomboides) Sand seatrout (Cynoscion arenarius) Southern kingfish (Menticirrhus americanus) Gulf kingfish (Menticirrhus littoralis) Black drum (Pogonias cromis) Star drum (Stellifer lanceolatus) Atlantic spadefish (Chaetodipterus faber) Striped mullet (Mugil cephalus) Atlantic threadfin (Polydactylus octonemus) Southern stargazer (Astroscopus y-graecum) Emerald sleeper (Erotelis_ smaragdus) Fillfin goby (Bathygobius soporator) Darter goby (Gobionellus boleosoma) Sharp tail goby (Gobinellus hastatus) Freshwater goby (Gobionellus shufeldti) Naked goby (Gobiosoma bosci) Code goby (Gobiosoma robustum) Clown goby (Microgobius gulosus) Atlantic cutlassfish (Trichiurus lepturus) Spanish mackerel (Scomberomorus maculatus) Harvest fish (Peprilus alepidotus) Gulf butterfish (Peprilus burti) Blackfin searobin--cPrioUot~~bio) Bighead searobin (Prionotus tribulus) Bay whiff (Citharichthys spilopterus) Fringed flounder (Etropus crossostus) Southern flounder (Paralichthys lathostigma) Lined sole (Achirus lineatus) Blackcheck tonguefish (Symphurus plagiusa) Least puffer (Sphoeroides parvus) Striped burrfish (Chilomycterus
Fresh Harsh Spotted gar (Lepisosteus ocu~atus Gulf menhaden (Brevoortia patronus) Bay anchovy (Anchoa~tchilli) Carp (CyprinusCarpio) --~-~--Black bullhead (Ictalurus melas Yellow bullhead (Ictalurus~lis) Channel catfish (Ictalurus punctatus) Sheep shead minnow (Cyprinodon variegatus)
r
Table 10. Continued.
Golden topminnovl (Fundulus chrysotus) Bayou killifish (Fundulus pulvereus) Tidewater silve.rside (Menidia beryllina) Gulf pipefish (Syngnathus scov~l1i) Flier (Centra~chus macropterus) Banded pygmy sunfish (Elassoma zonatum) Bluegill (Lepomis macrochirus) Spotted sunfish (Lepomis punctatus) Bantam sunfish (Lepomis. syrnmetricus) Largemouth bass (Micropterus salmoides) Black crappie (Pomoxis nigromaculatus) Pinfish (Lagodon rhomboides) Silver perch (Bairdiella chrysura) Spotted seatrout (Cynoscion nebulosus Spot (Leiostomus xanthurus) Atlantic croaker (Micropogon undulatus) Striped mullet (Mugil cephalus)
Fat sleeper (Dormitator maculatus) Naked goby (Gobisoma bosci) Clown goby (Microgobius gulosus) Atlantic cuttlefish (Trichiurus lepturus) Lined sole (Achirus 1ineatus) Hogchoker (Trinectes macu1atus)
Swamp Forest Spotted gar (Lepisosteus ocu1atus) Longnose gar (Lepisosteus osseus) Shortnose gar (Lepisosteus p1atostomus) Alligator gar (Lepisosteus spatula) Bowfin (Amia calva) Gizzard shad (Dorosoma cepedianum) Threadfin shad (Dorosoma petenense) Carp (Cyprinus carpio) Golden shinner (Notemigonus cryso1eucas) Lake chub sucker (Erimyzon sucetta) Blue catfish (Icta1urus furcatus) Black bullhead (Icta1urus melas) Yellow bullhead (Icta1urus natalis) Channel catfish (Icta1urus punctatus) Tadpole madton (Noturus gyrinus) Flathead catfish (Py1odictis olivaris) (Aphredoderus sayanus) Golden topminnow (Fundulus chrysotus) Mosquitofish (Gambusia affinis) Least killifish (Heterandria formosa) Sailfin molly (Poecilia latipinna) Yellow bass mississippiensis)
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Table 10. Continued.
Flier (Centrarchus macropterus) Banded pygmy sunfish (Elassoma zona tum) Bluegill (Lepomis macrochirus) Bluegill X spotted sunfish (Lepomis punctatus X
macrochrirus) Spotted sunfish (Lepomis punctatus) Bantam sunfish (Lepomis symmetricus) Largemouth bass (Micropterus salmoides) Black crappie (Pomoxis nigromaculatus) Striped mullet (Mugil cephalus)
Brackish Marsh Atlantic stingray (Dasyatis sabina) Spotted gar (Lepisosteus oculatus) Shortnose gar (Lepisosteus platostomus) Ladyfish (Elops saurus) Speckled worm eel (Myrophis punctatus) Shrimp eel (Ophichtus gomesi) Skipjack herring (Alosa chrysochloris) Atlantic thread herring (Opisthonema oglinum) Scaled sardine (Harengula pensacolae) Inshore lizardfish (Synodus foetens)
Sea catfish (Arius felis) Diamond killifish (Adinia xenica) Rainwater killifish (Lucania parva) Gulf killifish (Fundulus gran~ Bayou killifish (Fundulus pulvereus) Longnose killifish (Fundulus similus) Sailfin molly (Poecilia latipinna) Rough silverside (Membras martinica) Chain pipefish (Syngnathus louisianae) Pinfish (Lagodon rhomboides) Silver perch (Bairdiella chrysura) Spotted seatrout (Cynoscion nebulosus) Spot (Leiostomus xanthurus) Red drum (Pogonias cromis) Striped mullet (~cephalus) Fat s]peper (Dormitator maculatus) Sharptail goby (Gobionellus hastatus) Freshwater goby (Gobionellus shufeldi) Southern flounder (Paralichtys legostigma)
Source: D. W. Mabie, in unpublished MS.
up over 75 percent of the total catch in their samples. Total fish biomass in Barataria Bay is highest in the spring and is related to a general inshore movement of various marine species. Lowest biomass and occur in winter, concurrent with lowest temperatures.
Many marine species spawn in the Gulf and then move into the estuaries, where they remain until nearly mature. Included in this category are: Croaker (Micropogon undulatus), Spot, Sand seatrout (Cynoscion arenarius), Sea catfish (Arius felis), menhaden.~St~iped mullet (Mugil cephalus), and Bay whiff (Citharichthyes spilopterus). Reduction in size of the estuarine zone through intrusion of more saline water would have the effect of reducing population sizes of fish that undergo maturatiDn here.
Species such as the Bay anchovy and Tidewater silverside (Menidia beryllina) may be closest to truly estuarine species. The bulk of their populations occupy the estuarine zone throughout their entire life cycles.
Among freshwater forms, catfish (Ictalurus sp.) are harvested commercially, particularly in the area of Lac des Allemands (J. W. Day, Jr., personal communication). Swamp forest bayous and freshwater lakes support diverse fish communities, many of which are exploited for sporting or lesser commercial use. This category includes gars (Lepisosteus sp.), Bowfin (Amia calva), Carp (Cyprinus carpio), Sunfish (Lepomis sp.), Largemouth bass (Micropterus salmoides), and Crappie (Pomoxis sp.). The Mosquitofish (Gambusia affinis) is extremely abundant in freshwater areas and is undoubtedly an important component of aquatic predatory food chains.
A detailed analysis of menhaden harvest data will be discussed in a separately published section.
Amphibians and Reptiles
Reptile and amphibian communities apparently show a general trend of decreasing diversity as one moves from the swamp forest habitat through fresh, intermediate brackish, and saline marshes (D. Mabie, ished MS). The s
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tural diversity of swamp forest vegetation may be related to the relatively high diversity of the herpetofauna (amphibians and reptiles) in this habitat (see Schoener and Schoener 1971, MacArthur et al. 1962). Relatively high salinities may limit species diversity in the coastal marsh environments, though numerous reptiles and amphibians around the world have adapted to high salinities. Mating choruses of the Eastern narrowmouthed .toad (Gastrophryne carolinensis) have been observed in brackish water in the marshes north of Grand Isle (Hebrard, personal observation). The Gulf salt marsh snake (Natrix fasciata clarki) will not drink salt water, while the Broadbanded water snake (Natrix fasciata confluens) that occurs in freshwater areas will, and will succumb to its effects (Pettus 1963).
Chenier ridges in the coastal marshes apparently act as terrestrial islands within the marsh, supporting a herpetofauna similar to more inland localities. Snakes are sometimes abundant on these wooded ridges. Chenier Caminada, north of Grand Isle, supports such species as Speckled kingsnake (Lampropeltis gelulus), Western ribbon snake (Thamnophis proximus), and racer (Coluber constrictor) as well as the Cottonmouth (Agkistrodon piscivorous) (Hebrard, personal observation). Mabie (unpublished MS) states that natural levees and spoil banks serve as centers of concentration for reptiles and amphibians.
Population studies of amphibians and reptiles on the Louisiana coast have been few. These animals fill a variety of roles ranging from detritivores (tadpoles), to herbivores (some turtles) to carnivores (snakes). Their abundance in this region makes them particularly suitable for future study.
Tinkle (1959) conducted a study of snake populations in a swamp habitat near New Orleans (not in Barataria Basin). He found the greatest abundance and diversity of snakes along ridges and noted changes in local densities associated with changes in vlater level.
Table 11 presents population estimates for alligators by marsh type along the Louisiana coast (from Joanen and McNease 1972). Though not specific for Barataria Basin, these are the only data currently available. The estimates are
Table 11. Percentage alligator populations according to marsh zone and marsh types.
Marsh Type
Fresh
Intermediate
Brackish
Total Acreage
Percent Population, Percent Acreage/ Harsh Zone
Chenier Plain
Pop. Est. Acreage (%)
23.66 425,100
20.54 354,594
13.05 332,466
1,112,160
57.25 34.99*
HARGH zmms
Sub Del ta
Pop. Est. Acreage (%)
12.86 744,900
5.85 230,400
15.74 838,786
1,814,086
34.46 57.08
Active Delta Pen . .:enL P~i.ceut
of Pop/ of Acre-
Pop. Est. Acreage Marsh age/Harsh
(%) Type Type
3.81 129,340 40.33 40.88
3.78 106,800 30.17 21. 77
0.70 15,747 29.49 37.35
251,887
8.29 7.93
*Total population some 170,000 in 1972. Source: T. Joanen and L. McNease. 1972. Population distribution of
alligators with special reference to Louisiana coastal marshes. Symp. Amer. Alligator Council, Lake Charles, La.
probably low as they do not reflect recent increases in alligator populations. Greg Linscombe of the Louisiana Wildlife and Fisheries Commission has gathered detailed data for alligator populations covering several years, but the data have not yet been summarized.
The alligator is commonly associated with fresh, intermediate, and slightly brackish habitats, according to Joanen and McNease (1972). Highest populations were found in intermediate marsh, and those areas with lakes, ponds, canals, or rivers with salinities below 10 ppt are preferred. Joanen and McNease determined that 34.5 percent of coastal Louisiana's alligator population was in the subde1ta region.
Chabreck (1971) found that crayfish comprise 61 percent of the alligator's food in fresh water, while in brackish water blue crabs comprised 50 percent of the diet. Alligators also eat birds, fiddler crabs, fish, insects, muskrats, turtles, shrimp, grasses, and snails.
Tables 12 and 13 give lists of reptiles and that occur in all habitats of
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88
·~~~~~~~~~~~.~.~~~O~~~~~~~~~~~~~~~~
Barataria Basin. These lists are taken from Mabie (unpublished MS) with updated information from Conant (1975). This list is subject to change and refinement as more information is gathered.
Table 12. Reptiles known or likely to occur in Barataria Basin (all habitats).
American alligator (Alligator mississippiensis) Snapping turtle (Chelydra serpentina) Alligator snapping turtle (Macroclemys temmincki) Stinkpot (Sternotherus odoratus) Mud turtle (Kinosternon subrubrum) Diamondback terrapin (Malaclemys terrapin) Mississippi map turtle (Graptemys kohni) Red-eared turtle (Chrysemys script~ Painted turtle (Chrysemys picta) Green anole (Anolis carolinensis) Ground skink (Leiolopisma laterale) Five-lined skink (Eumeces fasciatus) Broad-headed skink (Eumeces laticeps) Eastern glass lizard (Ophisaurus ventralis) Green water snake (Natrix cyclopion) Diamondbacked water snake (Natrix rhombifera) Yellow-bellied water snake (Natrix erythrogaster) Broad-banded water snake (Natrix fasciata confluens) Gulf salt marsh snake (Nat~~sciata clarki) Brown snake (Storeria dekayi) Wester:n ribbon snake (Thamnophis proximus) Mud snake (Farancia abacura) Racer (Coluber constrictor) Rough green snake (Opheodrys ~estivu~) Speckled king snake (Lampropeltis getulus) Cottonmouth (Agkistrodon piscivorous)
S()urce D. MS; R. ConanL 1975. A to reptiles and of eastern and central North America. HoughtonMifflin Co. Boston, Mass.; D. A. Rossman, personal communication.
Table 13. Amphibians known or likely to occur in Barataria Basin (all habitats),
Three~toed amphiuma (Amphiuma tridactylum) Lesser siren (Siren i~termedia) Central newt (Notophthalmus viridescens) Fowler's toad (Bufo woodhousei) Gulf coast toad (Bufo valliceps) Cricket frog (Acris crepitans) Spring peeper (Hyla crucifer) Green treefrog (Hyla cinerea) Squirrel treefrog (Hyla ~vire!la) Eastern narrow-mouthed toad (Gastrophryne
carolinensis) Bullfrog (Rana catesbeiana) Pig frog (Rana gryliO)---' Bronze frog (Rana clamitans) Southern leopard frog (Rana pipiens)
Source: D. W. Mabie unpublished MS; R. Conant. 1975. A field guide to reptiles and amphibians of eastern and central North America. HoughtonMifflin Co.) Boston, Mass.
Birds
Birds perform a variety of important ecological functions in coastal ecosystems of Louisiana, varying from herbivores to top carnivores. A large proportion are insectivorous to some degree and are undoubtedly important controls on insect populations. In order to handle the wide variety of bird types and their relationship to the coastal zone, seven major groups of birds will be discussed in the context of the environmental units (marsh types and swamp). The groups include: fishing birds, shore birds, birds of prey, wading birds, waterfowl, rails and gallinules, and passerines.
Findings from the Gosse1ink et al. (1976), Environmental Baseline Study (LOOP Report) are cited freely throughout this discussion (Mabie, unpublished MS). Although a portion of this
89
90
study was conducted on the west side of Bayou Lafourche (outside Barataria Basin) the results are still meaningful. Bayou Lafourche does not represent a significant barrier to highly mobile organisms such as birds.
A complete list of birds for all habitats of Barataria Basin is given in Table 14.
Table 14. A list of 216 species of birds identified in all habitats of Barataria Basin.
Common loon (Gavia immer) Horned grebe (Podiceps auritus) Eared grebe (Podiceps nigricollis) Pied-billed grebe (Pocilymbus podiceps) White pelican (Pelecanus erythrorhynchos) Brown pelican (Pelecanus occidentalis) Northern gannet (Morus bassanus) Double-crested cormorant (Phalacrocorax auritus) Anhinga (Anhinga anhinga) Man-O'-War bird (Fregata magnificens) Great blue heron (Ardea herodias) Great egret (Casmerodius albus) Snowy egret (Egretta thul~ Cattle egret (Bubulcus ibis) Reddish egret (Dichromanassa rufescens) Louisiana heron (Hydranassa tric~i~ Little blue heron (Florida caerulea) Green heron (Butorides vire;ce;S)~ Black-crowned night heron (Nycticorax nycticorax) Yellow-crowned night heron (Nyctanass~ violacea) American bittern (Botaurus lentiginosus) Least bittern (Ixobrychus exilis) Glossy ibis (Plegadis falcinellus) W11ite-faced glossy ibis (Plegadis chihi) White ibis (Eudocimus albus) Snow goose (Chen caerulescens) Hallard (Anasplatyrhynchos) Mottled duck (Anas fulvigula) Gadwall (Anas strepera) Pintail (Anas "acuta) Green-~,'ingedteal(Anas crecca) Blue-winged teal (Anas discors) American widgeon (Anas ~mericana) Northern shoveler ~tula clypeata) Wood duck (Aix ~El1'l~)
Table 14. Continued.
Redhead (Aythya americana) Ring-necked duck (Aythya collaris)
(~yt~E valisineria) Lesser scaup duck (Aythya affinis) Bufflehead (~ucephala_ albeola) Ruddy duck (Oxyura jamaicensis) Hooded merganser (Lophodytes cucullatus) Red-breasted merganser (Mergus serrator) Turkey vulture (CatharteS-aura) Black vulture (Coragyps atratus) Swallow-tailed kite (Elanoides forficatus) Mississippi kite (Ictinia mississippiensis) Red-tailed hawk (Buteo jamaicensis) Red-shouldered hawk (Buteo lineatus) Bald eagle (Haliaeetus leucocephalus) Marsh hawk (Circus cyaneus) Osprey (Pandion haliaetus) Peregrine falcon (Falco peregrinus) American kestrel (Falco sparverius) King rail (Rallus elegans) Clapper rail (Rallus longirostris) Sora (Porzana carolina) Purple gallinule (Porphyrula martinica) Common gallinule (Gallinula chloropus) American coot (Fulica americana) Piping plover (Charadrius melodus)
*Snowy plover (Charadrius alexandrinus) Semipalmated plover (Charadrius semipalmatus) Wilson's plover (Charadrius wilsonia) Killdeer (Charadrius vociferus) Black-bellied plover (Pluvialis squatarola) Upland sandpiper (Bartramia longicauda) Ruddy turnstone (Arenaria interpres) Common snipe (Capella gallinago)
*Spotted sandpiper (Act it is macularia) Solitary sandpiper (Tringa solitaria) Willet (Catoptrophorus semipalmatus)·
*Greater yellow-legs (Tringa melanoleuca) *Lesser yellow-legs (Tringa flavipes)
Red knot (Calidris canutus) *Pectoral sandpiper (Calidris melanotos) White-rumped sandpiper (Calidris fuscicollis)
*Baird's sandpiper (Calidris bairdii) Least sandpiper (Calidris minutilla) Dunlin (Calidris ~lpina) ---~-----
Dowitcher (Limnodromus griseus, L .. sco19pac!=us)
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92
Table 14. Continued.
Semipalmated sandpiper (Calidris pus ilIa) Western sandpiper (Calidris mauri) Marbled godwit (Limosa fedoa-)---Sanderling (Calidris alba) Avocet (Recurvirostra~ricana) Black-necked stilt (Himantopus mexicanus)
*Wilson's phalarope (Steganopus tricolor) Herring gull (Larus argentatus) Ring-billed gull (Larus delawarensis) Laughing gull (Larus atricilla)
*Franklin's gull (Larus pipixcan) *Bonaparte's gull (Larus philadelphia) *Gull-billed tern (Gelochelidon nilotica) Forster's tern (Sterna forsteri) Common tern (Sterna hirundo) Least tern (Sterna albifrons) Royal tern (Thalasseus maximus) Sandwich tern (Thalasseus sandvicensis) Caspian tern (Hydroprogne caspia) Black tern (Chilidonias nigra) Black skimmer (Rynchops niger) Rock pigeon (Columba livia) Mourning dove (Zenaida macroura) Yellow-billed cuckoo (Coccyzus americanus) Black-billed cuckoo (Coccyzus erythophthalmus) Groove-billed ani (Crotophaga sulcirostris) Barn owl (Tyto alha) Great horned owl (Bubo virginianus) Common screech owl (Otus asio)
*Burrowing owl (Speot~c~ularia) Barred owl (Strix varia) Chuck-Will's-Wido~ (Caprimulgus carolinensis) Common nighthawk (Chordeiles minor) Chimney swift (Chaetura pelag~ Ruby-throated hummingbird (Archilochus colubris) Belted kingfisher (Megaceryle alcyon alcyon) Common flicker (Colaptes auratus) Pileated woodpecker (Dryocopus pileatus) Red-bellied woodpecker (Centurus carolinus Red-headed woodpecker (Melanerpes erythrocephalus) Yell.ow~bellied (Sphyrapicus varius) Do~roy woodpecker (Dendrocopos pubescens~)~-----Eastern kingbird (Tyrannus tyrannus) Great crested flycatcher (Myiarchus crinitus) Eastern phoebe (Sayornis phoebe) Empidonax sp.
Table 14. Continued.
Eastern wood pewee (Contopus virens) Tree swallow (Iridoprocne bicolor) Barn swallow (Hirundo rustica) R01Jgh-winged swallow (Stelgidopteryx ruficollis) Purple martin (Progne sub is) Blue jay (Cyanocitta crfStata) Common crow (Corvus brachyrhynchos) Fish crow (Corvus ossifragus) Carolina chickadee (Parus carolinensis) Tufted titmouse (Parus bicolor) Northern house wren (Troglodytes aedon) Carolina wren (Thryothorus ludovicianus) Marsh wren (Telmatodytes palust~i~) Sedge wren (Cistothorus platensis) Northern mockingbird (!1~musp()lygJ()t1:0s) Gray catbird (Dumetella carolinensis) Brown thrasher (Toxostoma rufum) American robin (Turdus migratorius) Wood thrush (Hylocichla mustelina) Hermit thrush (Catharus guttata) Swainson's thrush (Catharus ustulata) Gray-cheeked thrush (Catharus minimus) Veery (Catharus fuscescens) Eastern bluebird (Sialia sialis) Blue-gray gnatc2tcher (Polioptila caerulea)
Golden-crowned kinglet (Regulus satrapa) Ruby-crowned kinglet (Regulus calendula) Water pipit (Anthus spinoletta) Cedar waxwing (Bombycilla cedorum) Loggerhead shrike (Lanius ludovicianus) European starling (Sturnus vulgaris) White-eyed vireo (Vireo griseus) Yellow-throated vireo (Vireo flavifrons) Solitary vireo (Vireo solitarius) Red-eyed vireo (Vireo olivaceus) Black-and-white warbler (Mlliotilta varia) Prothonotary warbler (Protonotaria citrea) Swainson's warbler (Limnothlypis swainsoni) Worm-eating warbler (Helmintheros vermivorus) Golden-winged warbler (Vermivora chrysoptera) Blue-winged warbler (Vermivora pinus) Tennessee warbler (Vermivora peregrina) Orange-crowned warbler (Vermivora celata) Northern parula warbler (Parula americana) Yellov7 warbler (Denjroica petechia) Magnolia warbler (l?endroica magnolia)
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94
Table 14. Continued.
Cape may warbler (Dendroica tigrina) Black-throated blue warbler (Dendroica caerulescens) Myrtle warbler (Dendroica coronata) Black-throated green warbler (Dendroica virens) Cerulean warbler (Dendroica cerulea) Blackburnian warbler (Dendroica fusca) Yellow-throated warbler (Dendroica dominica) Chestnut-sided warbler (Dendroica pensylvanica Bay-breasted warbler (Dendroica castanea) Blackpoll warbler (Dendroica striata) Prairie warbler (Dendroica discolor) Palm warbler (Dendroica palmarum) Ovenbird (Seiurus aurocapillus) Northern waterthrush (Seiurus noveboracensis) Louisiana water thrush (Seiurus motacilla) Kentucky warbler (Geothlypis formosa) Common yellowthroat (Geothlypis trichas) Yellow-breasted chat (Icteria virens) Hooded warbler (Wilsonia citrina) American redstart (Setophaga ruticilla) House sparrow (Passer domesticus) Bobolink (Dolichonyx oryzivorus) Eastern meadowlark (Sturnella magna) Redwinged blackbird (Agelaius phoeniceus) Orchard oriole (Icterus spurius) Baltimore oriole (Icterus galbula) Boat-tailed grackle (Cassidix major) Common grackle (Quiscalus guis~ Brown-headed cowbird (Molothrus ater) Scarlet tanager (Piranga olivace~ Summer tanager (Piranga rubra) Northern cardinal (Cardinalis cardinalis) Rose-breasted grosbeak (Pheucticus ludovicianus) Blue grosbeak (Guiraca caerulea) Indigo bunting (Passerina cyanea) Dickcissel (Spiza americana) Rufous-sided towhee (PiEil()~ UJ -n-c-m-__ m __ ,
Sav;:mnah sparrow (Passerculus sandvJichensis-sparrow (Ammospiza '
Seaside sparrow (Ammosp~a-;arit Wl1ite-throated sparrow (Zonotrichia albicol1is Swamp sparrow (~e~ospi~~ georgiana) Song sparrow (Melospiza melodia)
*Birds that may occur in this area (personal communication, Robert J. Newman) but were not
observed by either Mabie or Hebrard.
Source: D, W, Mabie, unpublished MS.
Fishing Birds (gulls, terns, pelicans, skimmers)
Seasonal occurrence of fishing birds along the beach at Bay Champagne on the coast just east of the mouth of Bayou Lafourche is given in Table 15. The offshore and nearshore environments are used primarily as feeding and resting areas by
Table 15. Seasonal occurrence of fishing birds along beach area of Bay Champagne.
All N D J F M Year
Herring gull x x x x (Larus argentatus)
Ring-billed gull x x x x x (Larus delawarensis)
Laughing gull x x x x x x (Larus atricilla)
Forster's tern x x x x x x (Sterna forsteri)
Common tern x x x x (Sterna hirundo)
Royal tern x x x x x x (Thalasseus maximus)
Caspian tern x x x x (Hydroprogne caspia)
Black skimmer x x x x x x (Rynchops niger)*
White pelican x x x (Pelecanus erythrorhynchos)
Browne pelican x x x (Pelecanus occidentalis)
*Dominant species Source: Helga Cernicek, Observer
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96
.----~~~~~~-~~~~~~~~~~~---
many fishing birds and some waterfowl (e.g., Lesser scaup). Although not restricted exclusively to offshore and nearshore environments, the Brown pelican has been observed almost entirely in these habitats.
The abundance of fishing birds is influenced by seasonal migration, with the exception of the Black skimmer, Brown pelican, Laughing gull, Forster's tern, Royal tern, and Caspian tern, which are year-round residents of Louisiana (Lowery). These species eat primarily fish and shrimp.
The Brown pelican. which became extinct in Louisiana around 1961, has been reintroduced and is struggling to survive once again. Queen Bess Island in Barataria Bay has been the nesting site. Approximately 200 individuals were observed on 29 March 1974, with another 100 young birds in the nest. A 1975 survey revealed only 25 pairs with 13 young produced (Ray Aycock, personal communication). One hundred new birds were introduced in 1975 (Ralph Latapie, personal communication). Food of the Brown pelican consists entirely of fish, chiefly menhaden and mullet (Bent 1922).
The White pelican, a migratory species of fishing bird, was first observed during the LOOP study in October 1973. Approximately 1,000 of these large white birds were seen in the vicinity of Airplane Lake and Bay Champagne from October through March, at which time the northward migration began that left the marsh bare of this species. On each aerial survey from October through March these birds were observed feeding in a freshwater impoundment and on several occasions along the beach area of Bay Champagne. Scattered individuals were spotted in saline and brackish areas within the mRrsh
Shorebirds (plovers, sandpipers, 9 etc. .. )
Thirteen of shorebirds were identi-fied along the beach environment of Bay Champagne by LOOP study Table 16 shows the .. patterns of seasonal occurrence for these 13 species. The Western sandpiper and Semipalmated sandpiper were found to be the most abundant overall. The plovers. sandpipers, and other shorebirds were found feeding along mud flats in
Table 16, Seasonal occurrence of shore birds along beach area of Bay Champagne 0
Nov Dec Jm. Feb Mar
Piping plover (Charadrius melodus) X
Semipalmated plover (Charadrius semipalmatus) X
Wilson I s plover (Charadrius wilsonia) X
Black-bellied plover (Pluvialis squatarola) X
Ruddy turnstone (Arenaria interpres) X
Willet (Catoptrophorus semipa1matus) X
Dowitcher (Limnodromus sp.) X
Semipalmated sandpiper (Ca1idris pusilla)* X
Western sandpiper (Calidris mauri) X
Sanderling (Ca1idris alba) X
Dun1in (Ca1idris a1pina)
Killdeer (Charadrius vociferus)
Avocet (Recurvirostra americana)
*Dominant species Source: Helga Cernicek, Observer
x
x X
X X
X
X X
X X X
X X X
X X X
X X X
X
X
the salt marsh and along the beach area of Bay Champagne.
Rails
Studies by Bateman (1965) and Oney (1954) of food items of the Clapper rail show this species
X
x
x
x
X
X
X
X
X
to be an important consumer species in the saline marsh. Among its foods are snails, crabs, insects, spiders, fish, and plants. During the LOOP study, the Clapper rail was found exclusively in the saline area with some intrusion into brackish
97
98
marsh zones. while the King rail was found predominantly in fresh marsh with some extension into brackish marsh. The small Sora rail is abundant during migration and during the winter.
The Red-shouldered hawk, Sparrow hawk, Marsh hawk, Osprey, and Barred owl were the birds of prey observed by LOOP study investigators. Peregrin falcons were observed near the chenier area east of Bay Champagne in the spring of 1972 by Hebrard (unpublished data). There are two active nests of the Southern bald eagle in Barataria Basin (Ray Aycock, personal communication).
Marsh hawks were found to be in all marsh environments during the LOOP study. Numerous individuals were seen in the salt and brackish marsh in November 1973. An Osprey was observed feeding in a freshwater impounded area on one occasion and in the swamp area along Bayou Citamon on several occasions. Barred owls were seen only in the swamp environment but were seen there year-round. Sparrow hawks were observed only during the winter months, usually sitting on power lines along roadsides.
Wading Birds
Wading birds comprise a large segment of the coastal bird populations, ranging in habitat from beaches to swamps. Ten species of wading birds were observed during the LOOP study, including Great egret, Snowy egret, Cattle egret. Reddish egret, Louisiana heron, Little blue heron, Great blue heron, Black-crmvned night heron, Yellowcrowned heron, Green heron, White ibis, Glossy ibis, White-faced ibis, American bittern, and Least bittern.
Data collected from aerial surveys during the LOOP study show seasonal abundance, density. and marsh preference of many of the species listed (Tables 17 through 20). Densities of all
Table 22. Four transects the
same .l:Lne ~.;rere tlmvn by LOOP study investigators on the same day once a month from August 1973 through July 1974. From the numbers calculated per day, the lowest density usually occurred at midday or early afternoon. This daily variation is related to the diurnal movement of wading birds from roosting areas to feeding areas that
may cover over 50 miles each day (Lowery 1974). Because of this factor, mean and peak numbers were used in the calculation of wading bird density by marsh type (Table 21). Definite changes occurred monthly in of birds by marsh type and abundance Peak numbers were seen during September and October of 1973, with a gradual decline beginning in November and continuing through March. Although density of the wading birds changed by marsh type during the year, the highest percentage of the total number of wading birds observed was usually in the saline marsh. Movement of virtually all species during November through March was related to migration, though not necessarily migration out of the state.
Of the herons and egrets observed in the LOOP study, the Snowy egret and Great egret were found to be the most abundant. The reddish egret was least abundant, with only two individuals ever seen at one time and only along the beach environment. Little blue herons were found in large numbers only in association with agricultural areas, except during the breeding season when they became associated with other egrets and herons within the heronries.
Ibises. Four species of ibis have been recorded in Louisiana (Lowery 1974), three of which were observed during the LOOP study. These included the White ibis, Glossy ibis, and Whitefaced ibis. Lowery (1974) considers the Glossy ibis to be rare in the state with only a few definite records from the Grand Isle area. White and White-faced ibises are abundant along the coast at all seasons, and the Glossy Ibis is permanent residents in the southeastern section though they are seldom observed (Palmisano 1971). Nearly all dark ibises (Glossy and ~fuite-faced) are restricted to marsh habitats, while the White ibises occur throughout the marshes and swamplands of southeast Louisiana. LOOP study aerial surveys showed that the ibises comprise a relatively small portion of. the total number of wading birds in the Barataria Basin.
Bitterns. The American bittern is most numerous on the Louisiana coast in ",inter when there is a large influx of migrants from the north "Jhi1e the Least bittern is only present in
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100
Table 17. Peak number of individual wading birds/lO()-acres-observed August 1973-July 1974 with a mean value for the year in the fresll marsh areas of Barataria Basin
Species 8/22 9/20 10/25 11/22. 12/21 1/30 2/22 3/29 4/26 5/13 6/26 7/30 Av
Great Egret (Casmerodius alb us)
Snowy Egret'" --(Egretta thula)
Cattle Egret (Bubulcuc ibis)
Reddish Egret"'''' (Dichromanassa rufescensj
Louisiana Heron (Hydranassa tricolor)
Little Blue Heron (Florida caerulea)
Great Blue Heron (Ardea herodias)
Black-Crowned lli~ht Heron'" (Nycticorax nycticorax)
Yellow-Crowned Night Heron (Nyctanassa violacea)
White Ibis"'''' (Eudocinus alb us)
Dark Ibi-s-- ---
Glossy (Pl~~~~ facinellus) \fuite Facen (Plegadi~ chihi) ",*
6.3 6.1
8.9 13.2
29.3 53
o 0
2.3 2.1
.9 3.9
.3 .2
o .07
o 0
14.3 0
o 1.1
5 1i.2 3.9 4.6
11. 3 1.7 6.4 19.9
8.2 .3 o 2.7
o o o 0
.5 .5 1. 7 1.9
.8 1.3 2.4 .3
.3 .2 .2 .4
o o 0 o
o o 0 o
.4 1.1 0 o
3.9 1 o .3
'" SnRwy Esret numbers also include il'llllature Little Blue Herons. "'* Blue list species.
Area observed: 1,280 acres.
Source: D. Ii. Mabrie >--.!!!!£.ub li shed !TIS.
1.5 1.2 .4 .7 3.9 3.2 3.6
3.5 3.7 2.1 4 2.3 4.8 6.8
.4 2.3 4.2 1.3 13.5 43.1 13.2
o o o o 0 o 0
2.5 .07 .2 .3 .2 .1 1.1
3 2.8 .1 .2 .08 1.9 1.5
.2 .07 .1 .2 .2 0 .2
o o o o .08 .08 .02
o o o o 000
o o o .4 o .08 1.4
.9 o o o .4 .9 .7
Table 18. Peak number of individual wading birds/lOO acres observed August 1973-July 1974 with a mean value for the year in the brackish marsh area along Bayou Lafourche.
Species 8/22 9/20 10/25 11/29 12/21 1/30 2/22 3/29 4/26 5/13 6/26 7/30 Av
Great Egret (Casmerodius albus)
Snowy Egr~ ---(~retta thula)
Cattle Egret (Bubulcuc ibis)
Reddish Egret"'* (Dichromanassa rufescens)
Louisiana Heron (Hydranassa tricolor)
Little Blue Heron (Florida caerulea)
Great Blue Heron (Ardea herodias)
Black-CrDl.ffied Night Heron"'* (Nycticorax nycticorax)
Yellow""Crmmed Night Heron (Nyctanassa violacea)
Hhite Ibis H
(Eudocinus albus) Dark Ibis - ---
Glossy (Plegadis facine1lus) White Faced (Plegadis chihi)**
8.5 15.8 6.4 18.6 2.6
9.8 18 10 14 9.3
000 o o
000 o o
4 10 1.1 1.1 2.6
1.7 2.7 .9 .6 .4
.09.4 .2 .2 .2
o .2 .3 o o
000 o o
000 o .4
o 13.3 5.3 o o
* Snowy Egret numbers also include immature Little Blue Herons ** Blue list species
Area observed: 1,120 acres
7.1 .9 1.B .7 2.4 11.8 4.2 6.7
3.8 1.3 2.7 3.2 3.2 10.6 Il.B 8.1
o 000000 0
o 000000 0
1.5 4 .8 2 1.5 2.1 5 2.9
.5 . 3 .09 0 . 2 2 . 7 1. 5 .9
.2 .2 0 ;09 0 .09 .09
o .2 0 0 0 0 0
o 000000 0
o o 0 0 0 5.6 :5
o O· 0 .6 .4 4.3 0
Table 19. Peak number of individual wading birds/IOO acres observed August 1973~July 1974 ylith a mean value for the year in the salt marsh area along Bayou Lafourche.
--------------------------------------------------------------------~---------------------------
Great Egret (Casmerodius albus)
Snowy Egret* -(Egretta thula)
Cattle Egret (Bubulcuc ibis)
Reddish Egret** (Dichromanassa rufescens)
Louisiana Heron (Hydranassa tricolor)
Little Blue Heron (Florida caerulea)
Great Blue Heron (Ardea herodias)
Black-Crowned Night Heron** (Nycticorax nycticorax)
Yellow~Crowned Night Heron (Nyctanassa violacea)
White Ibis*'" (Eudocinus albus)
Dark Ibis -----Glossy (Pie gad is facinellus) White Faced (Plegadis chihi)**
8/22 9/20 10/2.5 J 1/29 12/2J 1/30 2/22 3/29 4/26 5/13 6/26 7/30 Av
7.3 16.4 32 11.5 18.75 11.1 .7 1.1 3.9 2.5 20.5 16 11.8
12.7 21.4 35.5 17.2 7.8 10 3.1 2.6 12.3 8.7 29.6 37.1 16.5
00000 0 0 000 000
o 0 0 .07 0 .03 .03 0 Q .03 0 0 .01
2.8 8.6 10.2 2.9 14.9 5.0 3.6 .9 1.4 2.9 8.3 9 5.9
1.1 3.6 1.8 .7 .4 .03 .07 .07 .07 .07 .5.3 .73
.2 .2 .5 .5 .8 1 1.3 .4 .1 .O~ .1 .07 .44
.1 .07 .07 .4 .9 .07 0 .2 .07 .07 0 .03 .16
00000 0 0 0 0 0 000
3.6 .2 2.2 0 0 0 0 0 0 0 1.7 5.2 1.1
.4 6.3 1.3 1.9 0 0 .03 0 .4 .3 2.4 6.4 1.6
* Snowy Egret numbers also include immature Little Blue Herons ** Blue list species
Area observed: 2,720 acres Source: D. W. Mabie, unpubli~hed IDS.
Table 20. Peak number of individual wading birds/IOO acres observed August 1973-July 1974 with a mean value for the year in an impounded area north of the mouth of Bayou Lafourche
8/22 9/20 10/25 11/29 12/21 1/30 2/22 3/29 4/26 5/13 6/26 7/30. Av
Great Egret (Casmerodius albus)
Snowy Eg~-(Egretta thula)
Cattle Egret (Bubulcuc ibis)
Reddish Egret** (Dichromanassa rufescens)
Louisiana Heron (Hydranassa tricolor)
Little Blue Heron (Florida caerulea)
Great Blue Heron (Ardea herodias)
Black-Crowned Night Heron** (Nycticorax nycticorax)
Yellow-Crowned Night Heron (Nyctanassa violacea)
White Ibis** (Eudocinus albus)
Dark Ibis --Glossy (Plegadis tacinellus) Hhite Faced (Plegadi9' chihi)**
167 23.5 60 6
471 52 14.5 4
o 0 0 o
o 0 0 o
76 8 18 18.5 9.5
12 .5 1 1.5 .5
3.5 1 1 .5 1
o 2 0 o 0
000 o 0
o 0 37.5 o 0
7.5 0 60 75 0
* Snowy Egret numbers also include immature Little Blue Herons ** Blue lisl species
Area observed: 200 acres
o
o
o
o
2.5 3.5 16.5 40.5 15 1 13.5 29.1
6.5 31. 5 44.5 193 63.5 3 53 78
o o o 0 o o 0 o o
o o o 0 o o o o
17 25 1.5 6 8 1.5 10.5 16.6
o 0 o o o o 0 1.3
2 1 1 .5 .5 .5 .5 1
o 0 o .5 5.5 .5 0 .71
o 0 o o o 000
o 0 o o o o 0 3.1
o 0 o o o o 46.5 15.8
101
102
Table 21. Hading birds/lOO acres in the marsh environments of southeast Lou::'siana along a 400-m wide transect.
Aug. 22, 1973 Sept. 20, 1973 Oct. 25, 1973 Nov. 29, 1973 Dec. 21, 1973 Jan. 30, 1974 Feb. 22, 1974 ~larch 29, 1974 April 26, 1974 May 13, 1974 June 26, 1974 July 30, 31, 1974
Mean
31:2 52.3 18.3
5.2 7.3
18.2 7.5 5.3 5.0 3.5
11.4 23.5
Fresh
Peak
39.4 65.8 22.8 12.4 14.8 27.5 11.6 8.8 6.3 5.4
19.3 46.6
Brackish Saline
Mean Peak Mean Peak
13.1 25.0 12.0 24.6 26.3 55.0 34.4 48.5 9.7 23.9 60.9 77.3
15.4 34.6 24.1 35.3 6.6 15.6 29.3 43.7 5.4 13.2 17.3 25.2 3.8 5.4 5.8 8.5 2.5 4.9 4.3 5.0 3.6 4.8 13.2 17.3 3.5 6.2 9.9 14.6
20.4 31.0 51.6 58.1 12.1 22.9 39.2 74.2
*Herons: Louisiana Little Blue Great Blue Black-Crowned Night Yellow-Crowned Night
Egre~s:
American Snowy Cattle Reddish
Ibises: Hhite Glossy Hhite-faced
**1280 Acres of fresh marsh 1120 Acres of. brackish marsh 2720 Acres of saline marsh 5120 Total of all marsh types
Source: D. H. Mabie, unpublished ms.
spring and summer (Lowery 1974). Bitterns are secretive wading birds and are
rather difficult to observe. LOOP investigators walked transects in the marsh in search of these species. With great effort only one American bittern was found, this in the saline marsh. Several Least bitterns were flushed in fresh, brackish, and saline areas.
Nesting Colonies of Wading Birds Nesting generally occurs in large colonies
(heronries) with herons, egrets, and ibises all in the same colony. The adaptive significance of colonial nesting is poorly known. Allen and Mangels (1940) state that flock stimulation livery likely is essential to reproduction" in Black-crowned night herons. Darling (1952) concluded from studies bf gulls that social displays probably synchronize reproduction in breeding colonies. Mutual defense against predators has also been proposed as an advantage to colonial nesters. Table 22 shows location and species composition of known heronries in Barataria Basin.
Total of All Marsh Types
Mean Peak
17.2 25.7 37.1 49.6 39.0 47.3 17.6 27.2 18.8 24.0 14.9 19.4
6.8 12.5 4.1 4.5 9.1 11.1 6.9 9.9
34.8 41.6 29.4 46.0
Five heronries were located during the LOOP study all on islands within bays, Most consisted of Black mangrove trees (Avicennia nitida) that provided a structure for nest building. Ibises nested primarily in Cordgrass (Spartina alterniflora).
Table 22. Bird rookeries and their populations in Barataria Bay system,
1974 Survey (breeding pairs)
St, John the Baptist Parish--Lac des Allemands Little Blue heron--l,200 Cattle ,000 Great egret--50 Snowy egret--2,000 Louisiana heron--300 Black-crowned night heron--12
Lafourche Parish--Lake Bouef Little blue heron--700 Cattle egret--360 Snowy egret--840 Louisiana heron--300 Great egret--500 White ibis--500
Lafourche Parish--Gheens Great blue heron--75 Great egret--800 Little blue heron--200 Cattle egret--50 Snowy egret--50 Louisiana heron--25
Lafourche-St. Charles-Jefferson Parish--Lake Salvador
Little blue heron--350 Cattle egret--250 Snowy egret--lOO Louisiana heron--50
Jefferson Parish--Queen Bess Island Brown pelican--35 Little blue heron--5 Great egret--20 Snowy egret--65 Louisiana heron--175 Black-crowned night heron--S Dark ibis--140
103
104
Table 22. Continued.
Plaquemines Parish--Barataria Bay "East" Green heron--3 Little blue heron--240 Great Egret--l,150 Snowy egret--l,600 Louisiana heron--570 Black-crowned night heron--19 Dark ibis--200 White ibis--l,lOO
Jefferson Parish--Barataria Bay "West" Green heron--6 Little blue heron--40 Cattle egret--lO Great egret--790 Snowy egret--995 Louisiana heron--445 Black-crowned night heron--l Dark ibis--50 White ibis--20
St. Charles Parish--(T14S, R22E, Sll) Great egret--lOO Snowy egret--50 Cattle egret--3,OOO Louisiana heron--500 Little blue heron--2,OOO White ibis--lOO Dark ibis--lOO
St. John the Baptist Parish--Wallace (just S Hwy. 18) Great egret--500 Snowy egret--500 Cattle egret--500 Louisiana heron--500 Little blue heron--500 White ibis--500
St. Charles Parish--(T15S, R22E, S ) Night heron--75 Little blue heron--700 Great and Snowy egret--300
1975 Survey
Lafourche Parish-~2 mi S Little Lake/3 mi ENE Golden Meadow; a little S of West Fork Bayou LIOurs
Great egret--l,OOO Snowy egret--l,OOO Louisiana heron--l,OOO Little blue heron--l,OOO
Table 22. Continued.
Plaquemines Parish--NE Barataria Bay/S Bay Batiste; Big (or Bia) Island
Great blue heron--25 Great ,000 Snowy egret--1~OOO Little blue heron--25
Jefferson Parish--Queen Bess Island White ibis--200+ Brown pelican--25 pair + 13 young
Lafourche Parish--Midway between Lake Salvador and Gheens
White ibis--1,SOO Dark ibis--500
Source: Louisiana Wildlife and Fisheries Commission, Ray Aycock, Jr., compo
Nesting begins in April but varies from colony to colony. Weather conditions may influence the time of nesting (Palmisano 1971). Fledglings were observed in late May and early June 1974 during the LOOP study, but during this period newly hatched birds were also observed, indicating a prolonged breeding period from April through June.
These nesting colonies are important areas of wetland habitats. Zelickman and Golovkin (1972) found during a study of plankton communities near bird colonies that a correlation existed between a steady increase in abundance of domimant zooplankton species and the enrichment of the water with nutrients from bird excrement. Enrichment of the waters oc'curs not only during nesting periods but also throughout the year because of the daily aggregation of wading birds in roosts.
Data pertaining to the longevity of heronries are few. Most heron nests are situated above the ground, and Vermeer (1969) reports that heron colonies in Alberta were abandoned when trees died and fell. He further suggests that excrement from the colony itself may contribute to the death of trees, In the absence of structural damage to vegetation, however, heronries can be lived, main-
105
106
tained heronry on Avery Island has been continuously occupied for approximately 80 years (McIlhenny 1934; Lowery, personal communication).
Waterfowl Dabbling Ducks. This category of ducks is
characterized by their habit of feeding in relatively shallow water. Included are Mallard, Mottled duck, Black duck, Gadwall, Pintail, Green-winged teal, Blue-winged teal, Baldpate (American widgeon), and Shoveler. These ducks are the most diverse group of waterfowl that winter in coastal Louisiana. Data on density of dabbling ducks acquired by LOOP study investigators by marsh type from August 1973 to July 1974 are given in Tables 23 and 24. Abundances of individual species by habitat type are given in Tables 25 through 28.
The southward migration of dabbling ducks begins in August with the arrival of Blue-winged teal, and continues through December with the final Mallard migration into the state. In general, the main dabbler movements in the fall and winter are the Blue-winged teal and Pintail in August and September; Pintail in early October
Table 23. Puddle ducks*/IOO acres in the marsh environments of southeast Louisiana along a 400-m wide transect.**
Aug. 22, 1973 Sept. 20, 1973 Oct. 25, 1973 Nov. 29, 1973 Dec. 21, 1973 Jan. 30, 1974 Feb. 22, 1974 !>larch 29, 1974 April 26, 1974 clay 13, 1974 June 26, 1974 July 30, 31, 1974
;'Ha11ard Nottled Duck Gadwall Pintail Green-winged Teal Blue-winged Teal Baldpate Shoveller
Fresh
Nean
4.1 21.8 64.9 30.6 2.9 2.9
13.3 7.0 2.6
.15
. (110
0
Peak
15.7 34.6
146.0 47,5 6.2 5.2
23.2 13.5
5.8 .23 .15
0
Total of All Brackish Saline ~larsh Types
Nean Peak Bean Peak Nean Peak
5.3 10.9 0.1 0.4 2.2 4.3 14.1 20.3 5.4 7.3 11. 4 16.2
110.4 137.7 8.4 20.5 44.9 69.3 20.6 29.4 35.7 60.4 31. i 42.7 11.6 32.6 75.1 89.8 43.1 48.6
ll5.3 124.6 ll8.2 170.6 88.7 118.8 53.9 76.1 37.2 42.6 34.5 39,6 13.4 18.4 30.2 36.6 10.3 15.2
2.5 3.6 0.70 1.4 1.6 3.0 .53 1. 25 .08 .22 .2 .39 .]'), 2(, .13 .11 .15 .01,4 .089 .13 .25 .083 .13
**1280 Acres of fresh marsh 1120 Acres of brackish marsh 2720 Acres of saline m~rsh 5120 Total of all marsh types
Table 24. !lean and peak numbers of puddle ducks seen in each marsh type and total (mean and {leak) numbers of puddle ducks seen for all marsh types.
Aug. 22, 1973 Sept. 20, 1973 Oct. 25, 1973 Nov. 29, 1973 Dec. 21, 1973 Jan. 30, 1974 Feb. 22, 1974 March 29, 1974 April 26, 1974 Nay 13, 1974 June 26, 1974 July 30, 31, 1974
Fresh
Nean
53 279 831. 5 391. 5 37.75 37.25
170.75 90 33.25
2 .5
o
l'eak
201 443
1870 609
79 66
297 173
74 3 2 o
Brackish
Neall
59.5 158
1237.25 231 12~. 75
1291. 75 603.75 160.3
28 6 1.5
.5
Peak
123 228
1543 330 366
1396 852 206
40 14
3 1
Saline
NedU
3.25 149 230.5 971. 25
2043 3216.25 1011.5
288.6 19
2.25 3.75 3.75
feak
11 199 558
1644 2443 4643 1158
389 37
4 6 7
Tank Farm (Fresh)
Nean
161. 5 541
1131. 5 1458.5 5295.75 2271. 25 2190.25 822.6
10 1.5 1. 25 6
Peak
269 720
2093 1626 5883 2798 2595
996 20
3 3
16
Total No. Birds Seen
Hcan
277.25 1118.75 3430.75 3052.25 7506.25 6816.5 J957 1351. 6
80.25 11.75
7 10.25
P~:lk
367 1426 4573 3816 8120 8095 4386 1662
151 23 11 21
Table 25. Peak number of individual waterfowl species/100 acres observed Autust 1973-Ju1y 1974 in fresh marsh areas in Barataria Basin with a mean value for the period.
8/22 9/22 10/25 11/29 12/21 1/30 2/22 3/29 4/26 5/13 6/26 7/30 Av
Mallard Anas p1atyrhynchos
Mottled Duck* Anas fu1vigu1a
Gadl-lall;' Anas strepera
Pintail* Anas acuta
Green-1Vinged Teal Arras creCCa
Blue-Hinged Teal Anas dis cars
American Higeon Anas americana
Shove11er* Anas clypeata
Lesser Scaup** Aythya affinis
Red Head*-*---Aythva americana
Red-Breasted Merganser** }fergus serrator
Coot*** Fulica americana
o 2.5 3.7 .9 2.1
2 3 4.3 1.7 .6
o 0 .08 3.9 o
o 0 0 o o
o 0 0 o .6
13.6 34.2 133 46.6 3.7
o o 5.4 o o
o o o o 0
o o o o 15.6
o o o o o
o o o o .46
o o 23.4 15.6 o
Notes: *Pudd1e Ducks **Diving Ducks Source: D. H. Nabie, unpublished ms.
1 1.4 1.8 .15 o o o 1.1
.9 1.5 0 .62 .23 .15 o 1.3
2.8 8.2 .93 o o o o 1.3
o o 0 o o o o 0
.15 14.1 0 o o o o 1.2
3.9 8.110.5 5.4 .15 o o 21.6
o o o o o o o .45
o .15 1.8 1 o o o .25
o 6.6 1.9 3.7 o o o 2.3
o o o o o o o 0
o o o o o o o .04
o o o o o o .15 3.3
***Coots Area observed: 1,280 acres
107
108
Table 26. Peak number of individual ,.,aterfow1 species/lOO acres observed August 1973-Ju1y 1974 with a mean value for the year in brachish marsh areas in Barataria Basin.
Species 8/22 9/22 10/25 11/29 12/21 1/30 2/22 3/29 4/26 5/13 6/26 7/30 Av
Hallard Anas platvrhvnchos
Hott1ed Duck* Anas fu1vigu1a
Gadual1;' Anas strepera
Pintai1* Anas acuta -----
Green-Hinged Teal Anas~
B1ue-lVinged Teal A.Tlas dis cars ------
American Higeon Arras americana
Shove11er* Anas clypeata
Lesser Scaup** Avthva affinis
Re~)'-*----
Aythya america~ Red-Breasted ~!erganser**
Nergus serrator Coot**)':
Fulica americana
o .53
1 4.1
o o
o 0
o 1
9.9 16.1
o 0
o o
o o
o 0
o 0
o .17
7.5 1 2.7 10.7 .17
6.7 1.2 3.1 .7 1. 7
23.9 .17 13.4 40.5 26.7
o 1 2.1 5.3 0
o 0 26.7 18.6 0
102.5 27.1 3.5 26.7 21. 4
13.2 0 13.4 26.7 16.7
o o 0 4.5 .71
o o 23.9 28.6 20.7
o o 0 0 0
o o .44 1. 3 6.7
2.1 3.4 35.7 31.2 26.8
Notes: *Pudd1e Ducks **Di vinl' Ducks j'*'\-Coots Source: D. H. Habie, unpublished ms.
o o
.71 1.8
3.3 o
o o
o o
15.3 3.2
4.5 o
o o
8.2 3.4
o o
2.4 o
o o
o
1.1
o
o
o
.08
o
o
o
o
o
o
o
.26
o
o
o
o
o
o
o
o
o
o
o 1.9
.89 1. 9
o 8.9
o .7
o 3.9
.89 18.9
o 6.2
o .43
o 7.1
o 0
o .9
o 8.3
Area observed: 1,120 acreS
Table 27. Peak number of individual waterfowl species/lOO acres observed August 1973-Ju1y 1974 with a mean value for the year in salt marsh areas in Barataria Basin.
Species 8/22 9/22 10/25 11/29 12/21 1/30 2/22 3/29 4/26 5/13 6/26 7/30 Av
Hallard Anas platyrhvnchos
Hott1ed Duck* Anas fu1vigu1a
GadHall;' Anas strepera
Pintai1* Anas acuta -----
Green-Hinged Teal Anas crecca -----
Blue-Hinged Teal Anas dis cors ------
American \.;rigeon Anas americana
Shovel1er* ~~ ~
Anas clypeata Lesser Scaup 1"*
Aythy~ "lfinis Red Head**
Avthya americana Red-Breasted Herganser**
rlergus serrator Coot*,'o'·
Fulica americana
o 2.4
.03 .44
o o
o o
o 0
.4 6.8
o o
o o
o a
o o
o o
o o
.07 1.3 4 1.3 2.2
.88 .40 .69 .55 .73
o 21. 3 30.9 31.6 6.6
o 5.0 13.9 6.0 o
o 0 5.3 90.6 32.5
19.5 17.6 17.5 18.0 4.5
.11 21.5 27.7 23.1 3.6
.03 1.8 1,.73.8 4.4
o 1. 4 15.856.5 11,.8
o o o 0 o
o o 5.8 3.4 1.5
.44 .33 1.28 0 o
Notes: *Pudd1e Ducks **Divin? Ducks ***Coots Source: D. H. Habie, unpublished TllS.
o o o o o .9
.18 .22 .14 .22 .25 .4
4.7 o o o o 7.9
o o o o o 2.1
o o o o o 10.7
8.6 1.2 o o o 7.8
2.6 0 o o o 6.6
1. 3 0 o o o 1,3
.66 1.9 .14 o o 7.6
o 0 o o o
.25 .07 .11 o o
o 0 o o o
Area observed: 2,720
=
Table 28. Peak number of individual waterfowl species/lOO acres observed August 1973-July 1974 with a mean value for the year in an impounded area north of the mouth of Bayou Lafourche.
Species 8/22 9/22 10/25 11/29 12/21 1/30 2/22 3/29 4/26 5/13 6/26 7/30
Na11ard Anas Elatyrhynchos o 49.5 142 91 391 18.5 [) 0 .5 0 0 0
~lottled Duck* Anas fulvigula 2.5 78.5 11.5 13 .5 3 0 2 3.5 3 1.5 1.5 2
Gad\'la11 * Anas strepera 0 0 290 225 817.5 430.5 386.5 168 0 0 0 0
Pintail* Anas acuta 0 0 0 75 598 107.5 0 0 0 0 0 0 -----
Green-Winged Teal Anas crecca 0 0 0 0 37.S 537 280.5 36 0 0 0 0 -----
Blue-Hinged Teal Anas dis cors 133.5 266.5 309.5 178.5 500 76 87.5 159.5 7 0 0 6
American Higeon Anas americana 0 0 331 246 731 317.5 519.5 184 0 .5 0 0
Shovel1er* Anas clypeata 0 0 12 10.5 412 87.5 112.5 54.5 0 0 0 0
Lesser Scaup** Aythya af finis 0 0 0 <16 1372.5 543.5 383.5 1,30.5 22.5 6 0 0 0
Red Head** ~ americana 0 0 9 6 6 6 8.5 0 0 0 0 0
Red-Breasted Nerganser** Nergus serrator 0 0 0 0 190 105 70.5 63 0 0 0 0
Coot*** Fulica americana .03 6.3 4 8 6.8 5.9 0 0 0 0 0 .039
Notes: *Pudd1e Ducks **Diving Ducks ***Coots Area observed: 200 acres Source: D. H. Habie, unpublished IDS'
and early November; and the Mallard flights of November, December, and January (LWFC 1961).
In southeastern Louisiana 80 percent of the puddle ducks that wintered along the coastal areas were found in fresh marsh, 8.04 percent in intermediate marsh, 21.6 percent in brackish marsh, and 5.3 percent in saline marsh (Palmisano 1972a). Under normal conditions this would presumably be the general trend of waterfowl along the coast. The findings from the LOOP study show a different distribution that may be explained by high rainfall during the year of study (Mabie unpublished MS).
During December 1973, LOOP study investigators found 67.1 percent of the dabbling ducks in a freshwater impoundment in the salt marsh and only 0.8 percent in the fresh marsh. The brackish marsh held 4.2 percent, with 27.9 percent in the saline marsh. This was the general trend of dabbling duck distribution throughout the year.
Gadwall, American widgeon, and Blue-winged teal comprised the largest percentage of the
tabulated LOOP
Av
58,1,
10.2
193.1
65
74.3
143.6
194.1
57. 1,
234.5
3
35.7
2.6
109
110
The Wood duck is another waterfowl species occurring in Barataria Basin. It is found primarily in the heavily wooded swamps of the state and is a fairly common permanent resident (Lowery 1974). Several individuals were observed in the swamp area along Bayou Citamon during the LOOP study.
Diving Ducks • Diving ducks are char ac ter··· ized by their habit of feeding in relatively deep water. Because of the great numbers of Scaup (Aythya sp.) that winter in Louisiana, the diving ducks are the most numerous type of waterfowl wintering in the state (LWFC 1961). Data on density of diving ducks in the various marsh environments from August 1973 to July 1974 are given in Tables 29 and 30. Included among the diving ducks are Redhead, Canvasback, Scaup, Ringnecked duck, Ruddy duck, and Mergansers.
The main flights of diving ducks (primarily Scaup) arrive in late October and early November. These ducks remain in the state until March or April.
Results of a LOOP study census in December, the time of peak occurrence showed 73.9 percent of the population in an impounded freshwater site, 14.6 percent in saline marsh, 6.6 percent in brackish marsh, and 4.9 percent in fresh water.
Coots. Major fli_8hts of the American coot begin in October, but the majority of the first
arrivals are transients (LWFC 1961). This species is found primarily on freshwater lakes and brackish ponds throughout the state (Lowery 1974). Tables 31 and 32 show densities of coots by marsh type (Mabie unpublished MS).
LOOP study investigators found 74.9 percent of the coots censused in a freshwater impoundment. 2.0 percent in saline marsh, 23.1 percent in brackish marsh, and none in fresh marsh.
Louisiana Wildlife and Fisheries Data Hugh Bateman of the Louisiana Wildlife and
Fisheries Commission (LWFC) conducted aerial censuses of waterfowl populations. excluding geese and wood ducks. on the Louisiana coast since 1968. Summaries are presented in Tables 33 through 38. At this level of resolution it is not feasible to look at the data in terms of a
Table 29. Diving ducks*/100 acres in the marsh environments of southeast Louisiana alan?, a 400-m wide transect.**
Total of All Fresh Brackish Saline Harsh Types
~~-------
Bean Peak Hean Peak Nean Peak Bean Peak
Aug. 22, 1973 a a 0 a 0 0 0 0 Sept. 20, 1973 0 0 0 0 0 0 0 0 Oct. 25, 1973 0 0 0 0 a 0 0 0 Nov. 29, 1973 0 0 0.06 0.26 1.42 1. 58 0.77 0.83 Dec. 21, 1973 11. 0 15.6 19.1 23.9 18.3 21. 7 16.6 19.0 Jan. 30, 1974 0 0 9.6 28.5 16.0 28.1 10.6 17.1 Feb. 22, 1974 4.3 6.6 9.4 22.5 12.1 15.5 9.6 12.2 ~!arch 29, 1974 0.93 2.0 5.8 10.6 1.'1 2.1 1.9 2.8 April 26, 1974 0.93 3.75 1.5 3.5 0.91 2.0 1.0 1.8 ~!ay 13, 1974 a 0 0 a .06 .14 .03 .07 June 26, 1974 0 0 0 0 0 0 0 a July 30, 31, 1974 0 a 0 0 0 0 0 0
*Lesser Scaup **1280 Acres of fresh marsh Red Head 1120 Acres of brackish marsh Hergansers 2720 Acres of saline marsh
5120 Total of all marsh types
Table 30. Hean and peak numbers of diving ducks seen in each marsh type and total (mean and peak) numbers of diving ducks seen for all marsh types.
Fresh
Hean Peak
Aug. 22, 1973 0 0 Sept. 20, 1973 0 0 Oct. 25, 1973 0 0 Nov. 29, 1973 0 0 Dec. 21, 1973 142 200 Jan. 30, 1974 0 0 Feb. 22, 1974 55 85 March 29, 1974 12.3 25 April 26, 1974 12 48 May 13, 1974 a 0 June 26, 1974 0 0 July 30,31, 1974 0 0
Tank Farm Total No. Brackish Saline (Fresh) Birds Seen
Mean Peak Mean Peak Mean Peak Mean Peak
0 0 0 0 0 0 0 0 a 0 0 0 0 0 0 0 0 0 0 0 7.5 18 7.5 18 0.75 3 38.75 43 88.5 114 128 155
214 268 498.25 591 1852 2997 2706.25 3595 107.5 320 435.25 767 840 1297 1382.75 2075 105.75 252 329.5 421 534.75 908 1025 1383
64.6 119 21. 3 24 554.6 862 644.6 892 17.25 39 25 54 12.25 45 54.25 93 a 0 1. 75 4 3.25 12 5 12 0 0 a a 0 0 0 0 0 a 0 0 a a 0 0
specific drainage basin or for a specific habitat type. The data are presently being put on computer cards, after which they may be broken down according to a variety of geographical criteria.
As they are, these data clearly show arrival times of the in southeastern Louisiana. They also allow comparison of abundances on a
baS1S"
111
112
Table 31. Coots (Fu1ica americana)/100 acres in the marsh environments of southeast Louisiana long a 400-m wide transect. *
Fresh
Mean
Aug. 22, 1973 0 Sept. 20, 1973 0 Oct. 25, 1973 11. 2 Nov. 29, 1973 13.0 Dec. 21, 1973 0 Jan. 30, 1974 0 Feb. 22, 1974 0 March 29, 1974 0 April 26, 1974 0 May 13, 1974 0 June 26, 1974 0 July 30, 31, 1974 .039
*1280 Acres of fresh marsh 1120 Acres of brackish marsh 2720 Acres of saline marsh 5120 Total of all marsh types
Brackish
Peak Mean Peak
0 0 0 0 0.08 0.17
23.4 0.80 2.1 15.6 0.93 3.4
0 30.9 35.7 0 11.1 31.2 0 6.9 26.8 0 0 0 0 0 0 0 0 0 0 0 0
.15 0 0
Total of All Saline Marsh Types
Mean Peak Mean Peak
0 0 0 0 0 0 0.01 0.03 0.15 0.44 3.0 6.3 0.10 0.33 3.5 4.0 0.32 1. 28 6.9 8.0 0 0 2.4 6.8 0 0 1.5 5.9 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 .0097 .039
Table 32. Hean and peak numbers of coot (Fulica americana) seen in each marsh type and total (mean and peak) numbers of coots seen for all marsh types.
Tank' Farm Total No. Fresh Brackish Saline (Fresh) Birds Seen
Mean Peak Mean Peak Mean Peak Mean Peak Mean Peak
Aug. 22, 1973 0 0 0 0 0 0 0 0 0 0 Sept. 20, 1973 0 0 1 2 0 0 7.25 29 7.75 31 Oct. 25, 1973 143.75 300 9 24 4.25 12 461.5 603 618.5 879 Nov. 29, 1973 167.5 200 10.5 39 2.75 9 950 1000 1130.75 1150 Dec. 21, 1973 0 0 346.25 400 8.75 35 1170 1300 1525 1680 Jan. 30, 1974 0 0 125 350 0 0 254.25 422 379.25 572 Feb. 22, 1974 0 0 76.75 300 0 0 0 0 76.75 300 ~!arch 29, 1974 0 0 0 0 0 0 741. 6 822 741. 6 822 April 26, 1974 0 0 0 0 0 0 13.5 48 13.5 48 Hay 13, 1974 0 0 0 0 0 0 0 0 0 0 June 26, 1974 0 0 0 0 0 0 0 0 0 0 July 30,31, 1974 .5 2 0 0 0 0 0 0 .5 2
~
p
Table 33. September Haterfo1o,l
~[allard
Anas ~rhvnchos
Nottled Duck, Black Duck Anas fulvigul".. A. rub riDes
Gad'",all Anas ."..treper".
Pin tail Anas acuta -----
Green-Hinged Teal Anas~
Blue-Hinged Teal ~ discors
American Higeon Anae amelEJ!.aana
Shoveler
~J)-"-~!l'. ~!L~ a
Redhead Aythva americana
Canvasback ~ valisineria
Ring-necked Duck Av th'\' a col12 ris
Scaup Aythya affinis. A. marila
Ruddy Duck Oxyura jatlaicensis
Hooded ~!ergans er Lophodytes cucullatus
Source: Hull!! Bateman, CO!!!j2. I
populations (in thousands) for southeastern Louisiana (Atchafalaya Bay Lake
1968 1969 1970 1971 1972 1973 1974
.5 TRACE 0 0 0 <.5 <.5
21 ,,6 39 21 29 29 17
0 0 0 0 0 0 <.5
.75 TRACE 5 <.5 1 0 <.5
.5 TRACE 3 <.5 <.5 0 <.5
37 90 88 23 81 74 68
.5 TRACE 2 0 <.5 <.5 <.5
.75 TRACE 1 <.5 1 <.5 <.5
0 0 0 0 0 0 0
0 0 (j 0 0 0 0
0 0 0 0 0 0 0
0 0 0 0 0 0 0
0 0 0 0 0 0 0
0 0 0 0 0 0 0
Louisiana Wildlife and Fisheries Commission.
Passerines (perching birds) Forty-three percent of the 216 bird species
listed in Table 14 are passerines. Every species on the list beginning with the Eastern kingbird and ending with the Song sparrow are in this category. For convenience, several other species will be discussed with this group. These include Mourning dove, Rock pigeon, Yellow-billed cuckoo, Black-billed cuckoo, Chuck-wi11 1 s-widow, Common nighthawk, Chimney swift, Ruby-throated hummingbird, Belted kingfisher, and six species of woodpeckers. They may be divided into four categories based on seasonal occurrence in the coastal zone: winter residents, summer residents, permanent residents, and transients. They occupy virtually every habitat in the coastal zone at some time of year, from svlamp forest to beaches.
Borgne)
113
114
Table 34. October waterfowl populations (in thousands) for southeastern Louisiana (At'chafalaya Bay-Lake Bargne)
1968 1969 1970 1971
Nallard Anas p latyrhynchos .2 1 <.5 1
Nottled Duck, Black Duck Anas fulvigula) !2.. rubripes 30.8 42 37 29
Gad\olall Arras streoera 24.7 43 28 53
Pintail An,as acuta 39.2 63 40 1
Green-t"in ged Tea] Anas ccrecca 80.9 40 18 6
Blue-winged Teal Anas dis cors 145.5 237 180 100
American wigeon ..mas americanac' 29.4 70 37 26
Shoveler Spatula ~Deata 12.4 43 57 23
Redhead Aythva .§:.cericana 0 0 0 0
Canvasback Aythva valisineria 0 0 0 0
Ring-necked Duck ~thva collaris 0 0 <.5 <.5
Scaup Avthya affinis, A. marila 0 0 0 0
Ruddy Duck O~jura janaicensis 0 0 0 0
Hooded Herganser LOEhod~tes cucullatus 0 0 0 0
Source: Hugh Bateman, compo Louisiana Wildlife and Fisheries Commission.
1~inter Residents. Included in this category are the Yellow-bellied sapsucker, Tree swallow, House wren, Sedge wren, Robin, Hermit thrush, Golden-crowned kinglet. Ruby-crowned kinglet, Water pipit, Cedar waxwing. Solitary vireo. Orange-crowned warbler, Myrtle warbler, Palm warbler. Sharp-tailed sparrow, White-throated sparrow, Swamp sparrow, and Song sparrow (Lowery 1974).
These birds move into the coastal zone from more northern latitudes in the fall and in the spring. Of this group only the Sharp-tailed sparrow is restricted in habitat to the marsh. The rest can be found in a of habitats from swamp forest to marsh edge and on wooded cheniers and natural levees.
Summer Residents. These species migrate northward into the coastal zone to breed after
1972 1973 1974
<.5 <.5 <.5
24 1'; 27
25 6 111
1 16 88
26 16 96
124 292 142
22 52 78
3 3 67
0 0 0
0 0 0
<.5 0 0
0 0 0
0 0 0
0 0 0
Table 35. November waterfowl populations (in thousandS) for southeastern Louisiana (Atchafa1aya Bay-Lake Borgne)
~1allard
AnC1S platv_~hvn.~~~
Not t led Duck, Black Duck Anas fulvigula, A. rub riues
Gam'la11 Anas strepera
Pintail Anas acuta
Green-winged Teal Anas crecca
B1ue-,;inged Teal Anas dis cars
American wigeon Arras americana
Shoveler ~~."-
Redhead ~ a~ericana
Canvasb ack Avthya valisineria
Ring-necked Duck Aythya collaris
Scaup Avthya affinis, A. marila
Ruddy Duck O}~ura jamalcensis
Hooded Herganser Lophodytes cucullatus
Source: Hugh Bateman, co~.
1968 1969 1970 1971 1972 1973 1974
139 63 101 118 30 62 6C
h~ 30 33 40 36 39 29
456 326 484 269 186 705 32E
104 80 108 107 30 170 125
188 190 299 161 185 754 79
40 34 46 64 183 519 82
378 108 248 154 156 441 49
138 48 66 38 63 69 50
0 0 <.5 <.5 <.S
0 5 <.5 <.5
5 <.5 1 <.5 6 <.5 <.5
0 <.5 500 250 3 2
0 <.5 <.5 <.5 <.5 <.5
9 <.5 4 3 2 1 <.5
Louisiana Wildlife and Fisheries Commission.
wintering in Central and South America. Among the summer residents are Eastern kingbird, Yellowbilled cuckoo, Common nighthawk, Chimney swift, Ruby-throated hummingbird Great crested flycatcher, Acadian flycatcher, Rough-winged swallow, Purple martin, Wood thrush, White-eyed vireo, Yellow~ throated vireo, Prothonotary warbler, Swainson's warbler, Parula warbler, Yellow-throated warbler, Kentucky warbler, Yellowthroat, Yellow-breasted chat, Hooded warbler, Orchard oriole, Baltimore oriole, Summer tanager, Indigo bunting, and Painted bunting (Lowery 1974). Some individuals of some of these species may occur in small numbers on the Louisiana coast during mild winters. but populations are highest during spring and summer (Lowery 1974).
Of these, only the Yellowthroat breeds in marsh environments. A few
115
116
Table 36. i}ec-einber waterfowl populations (in thousands) for s-outheastern Louis-iana - \ \tchafalaya Bay-Lake Borgne)
1968 1969 1970 1971
Hallard Anas p1atvrhynchos 81 115 129 186
Hott1ed Duck, Black Duck Anas fulvigula, A. rubrioes 50 47 28 39
Gadwall Anas streDera 447 653 631 504
Pintail Anas acuta 42 72 270 126
Green-(,inged Teal 448 422 Anas~ 543 318
Blue-winged Teal 20 Anas discors 3:' 17 31
American wigelt>D Anas americana 234 264 433 ,86
;)noveler Spatula clypeata 58 59 61 31
Redhead Aythya american a 0 8 5
CanvasbacK ~ valisineria 0 5
Ring-necked Duck Aythva collaris 1 7 3 <.5
Scaup Aythya affinis, ~. marila 2 600 750 861
Ruddy Duck Oxyura jamaicensis 0 <.5 <.5
Hooded Herganser Lophodytes cucullatus 12 10 29 4
Source: Hugh Bateman, compo Louisiana Wildlife and Fisheries Commission.
cheniers and other forested ridges near the coast (e.g., Orchard oriole, Purple martin, Yellowthroat, Eastern kingbird), but the majority breed in forested swamps, bottomland hardwood, and forest edges.
Permanent Residents. These birds are present year-round and breed in the coastal zone. Included in this group are Rock pigeon, Mourning dove, Belted king fisher. Common flicker. Dileated woodpecker Red-bellied woodpecker, Downy ,"lOod~
Blue jay Common crm'7, Fish crOlv. Carolina chickadee, Tufted titmouse. Carolina wren, Marsh wren Mockingbird, Brown thrasher, Eastern blue-bird, Blue-gray , shrike, Starling, House sparrow, Eastern meadowlark, Redwinged blackbird, Common grackle, Boat-tailed grackle, Brown-headed cowbird, Cardinal, Rufoussided towhee, and Seaside sparrow (Lowery 1974).
1972 1973 1974
117 87
26 44
582 657
246 91
253 573
94 286
341 372
81 53
<.5
<.5
11 <.5
504 47
TRACE <.5
6 8
Table 37. January \,aterfowl populations (in thousands) for southeastern Louisiana (Atchafalaya Bay-Lake
1969 1970 1971 1972 1973 1974 1975
Ballard An~s p_~,~y:~J~Y_~~h5~~ 65 91 139 64 107 33 61
Nottled Duck, Black Duck Arras fulvisula, A. rub ripes 40 21, 57 27 37 31 34
Gad,;a11 Anas strepera 507 377 431 192 364 275 225
Pintilil Anas acuta 212 56 157 76 86 26 28
Green-,;inged Teal Anas crecca 448 355 344 185 274 350 123
Bl ue-winged Teal Anas dis cors 26 14 34 46 96 284 162
American wigeon An as americana 161 67 117 89 128 59 49
Shoveler Spatula clvpeata llO 36 48 54 45 62 43
Redhead Aythva a~erlcana 8 10 <.5
Canvasback Avthva valisineria 1 2 <.5 <.5
Ring-necked Duck Aythya collaris 2 3 7 10 8 <.j
Scaup Aythya aHinis, !=.. marila 595 650 850 844 762 136
Ruddy Duck OAyura jamaicensis 5 <.5 <.5 <.5
Herganser 12 8 13 0 5 2 5 Lophodytes cucul1atus
Source: Hugh Bateman, compo Louisiana Wildlife and Fisheries Commission.
Of these the Marsh wren, Boat-tailed grackle, and Seaside sparrow are not found far from coastal marshes. House sparrows and Starlings are restricted mainly to man-disturbed areas. The rest are found in a variety of wooded or agricultural areas.
Transients. This group of species utilizes coastal habitats only during spring and fall migration. All breed for the most part north of the coastal zone, many far north of Louisiana. They winter in Mexico, Central America, and South America. Included are Black-billed cuckoo, Chuck-Willis widow, Empidonax flycatchers, Eastern wood pewee, Barn swallow, Catbird, Swainson's thrush. Gray-cheeked thrush, Veery, Red-eyed vireo, Black~and~white warbler, Tennesse warbler, all Dendroica warblers (except Myrtle, Yellowthroated, and Palm) Ovenbird, Northern, and
Borgne)
117
118
Table 38. February HaterfoHl populations (in thousands-5 for southeastern Louisiana (Atchafalaya Bay-Lake Borgne)
'.969 1970 1971 1972
Nallard Anas p latyrhvnchos 38 74 97
Nottled Duck, Black DUCK z Anas fulvi2ula, ~. rubripes 38 36 46 c
GadHall Anas str2Dera 451 369 355 n
Pintail M
Anas acuta 137 47 113 z en
Green-Hinged Teal c: Anas~ 242 292 353 en
Blue-Hinged Teal Anas dis cars 72 37 56
American wigeon 481 50 231 Anas americana
Shoveler Spatula clvpeata 147 73 93
Redhead Aythva american~ a
Canvasback Avthya valisineria 5
Ring-necked Duck Aythya collaris 2 <.5 2
Scaup Aythya affinis, A. marila 210 528 558
Ruddy Duck Oxyura jamaicensis a <.5 <.5
Nerganser Lophodytes cucullatus 9 17 6
Source: Hugh Bateman, compo Louisiana Wildlife and Fisheries Commission.
Louisiana waterthrush. American redstart. Bobolink, Scarlet tanager. Blue grosbeak, and Dickcissel.
Patterns of spring migration of these species (and some summer residents) have been studied by Lowery (1945), Hebrard (1971). and Gauthreaux (1971). Over 70 species of songbirds cross the Gulf of Mexico almost every day beginning around the first of April and continuing until the middle of May. The great majority of these
migration shortly after • and at dawn.
Because of the length of, the trans-Gulf birds leave Mexico and areas further south at sunset are over water at da\"n and must continue flying until they reach land. Each day during the spring migration period. birds arrive over the Louisiana coast in tremendous numbers in late morning and all afternoon. Most continue inland
1973 1974 1975
34
Z z 0 34 0
n 375 n M M
z 54 z en en
c: c: en 186 en
334
161
80
19
267
2
to forested areas, but during bad weather many land in chenier woods. When such a "fallout" occurs, these coastal woodlands are literally full of vireos, warblers, thrushes, tanagers, grosbeaks, and bunt Nowhere on the northern Gulf of Hcxico do such concentrations of songbirds occur.
Table 39 shows the results of daily bird censuses on chenier Caminada during the spring of 1972 (Hebrard, unpublished data).
Mammals
Marine Mammals
The only marine mammal (cetacean) that is normally seen in Louisiana inshore waters is the Atlantic bottle-nosed dolphin (Tursiops truncatus). Dolphins can be observed feeding in Bay Champagne (at the western end of Barataria Basin's coastal edge), and it is not uncommon to see them as far north as Little Lake. This mammal is rather common within the coastal waters of Louisiana and is found in greatest numbers in the vicinity of passes connecting the larger bays with the Gulf (Lowery 1974). It should be mentioned that although this species is common, their numbers now appear to be reduced (Lowery 1974).
Food of the bottle-nosed dolphin along the northern Gulf coast consists primarily of mullet, but they also eat Puffer, Sheep shead , Needle gar, Black drum, Spotted trout, Flounder, Spot, and Croaker. They are also known to consume quantities of shrimp (Lowery 1974). This species is highly intelligent (Lilly 1969).
The Atlantic bottle-nosed dolphin is not the only marine mammal associated with the coastal waters of Louisiana, but it is the only species recorded from the Barataria Basin area. The checklist of mammals of Louisiana by Lowery (1973) gives 21 species of marine mammals that could occur along the Louisiana coast.
Terrestrial Mammals
Mammals of greatest economic and ecological importance in the marsh and swamp environments are the Muskrat (Ondatra zibethicus , (Myocastor coyp~s)-; Raccoon • l1ink
119
I-' N o
Table 39. Migrant species of birds observed 21 March-10 May 1972 in the Carninada Chenier.
Spec1eD
Mourning Dove (Zenaida ll"~1c:rolln:a)
Yello .... -billed C~Coccvzus <.itmer"fC{lnl.<:J) Black-billed Cuckoo (Cocc~..ii-em~~1C!u6) COllmlon Nighthawk (Q.:.ordcilcs minor) Ruby-throated HUm:D1ngblrd (Archilochus colubTia) Yello .... -be1l1ed Sapsucker (Sphyrllp1culJ "ari.~!~)Eastern Kingbird (Tyrannu:!. _t .. yr .... ~ .. ~ . .':!.E) Acadian Flycatcher (~}~":'.:!. ~~..12E..) Least Flycatcher (Emp1dona:r. ~.u~) Eastern "ood Pewee (0_r~~ v1:ren~) Rough-winged 5 .... a110 .... (~~~gfdoptel'f)( Euficoll;(s) Barn S .... al101o' (H1rundo n.:st,ic,:.) Purple Kartin (~r.!.£ Bu.bi;)-Blue Ja:v (Cyanoc1t~ ££1£!.J.~{I) Northern Mouse Wren (!.~.~o:d~t:.!:!.~)
Carolina. Wren (D'~J:1~~ }~o_vJ._~.I~) I"crt1ClT. ~ock1ngbird (~llIlU'" P01vglottos) Gray C.atbll"d (Dur:letclla s...;J~('!:nl>ns1~ Brown Thrasher (T,'>;OBtoC': rufum) '..'ood Thrush (HvJo~~u~-tei!na) S .... ainson's Th~(~<1~tu!,[)ta) Gray-cheeked Thruah- (C.Jt~~.I!:!E m1nil:J~) Veery (Catharus (uscescens)
Ruby-crovned Kin~t (Regulus c:ale~2....';:!.~) Cedar wa:xving (!lombyc:illa ~) \niire-eyed Vireo (Vireo sriseus) Yel]o1O-throated Vireo (Vir('o :"lav1frons) Red-eyed Vireo (Vireo o11vac:e-",-)-Philadelphia Vireo (Vireo ~1adelpb:!cuo) Black and \Jhlte Warbler (Hnioti}ra varia) Prothonotary Warbler (Protonotar1a ~IO) S .... ainson's \,'arbler (!l..mnorhlvpis a,",ai~n_l) \,Iorm-eating Warbler (Heh::itheroll ven.tl1vorus) Golden-.... inged Warbler (Ve(;ivora chryuo?te~) Blue-.... inged Warbler (y~~) Tennessee Warbler (~ peregrina) Orange-crowned Warbler (Vermivor., cel.:ttlO) Northern Parula Warbler (Pa~-J;-::;-:n~<l, 'idlo,", Warbler (Den~~ pete--zh~ KagnoliB l.Iarbler tDendr2i~ m..1snoli.E) Cape M.:ty Warbler (Dendroic,a Ul':rina) Hyrt1e Warbler (Dendroica coronata) Black-throated Green ~3.rbler (gendro::ca viren6) Cerulean Warbler (DendroiCll ce'~l.;ar---Blackburnian Warbl~n~~cil) Yello .... -throated Warb1~-;--r~1~mtnicil) Chestnut-sided W;ubler (~ndro1C:11 pensylva'lica) &.ay-breasted Warbler (Dendroic.::! Castanea) Blackpoll Warbler {Dendr~"~ Prairie Warbler (Dei1dfo~d1;7olor) Ovenbird (Seiuru8~1~
;:; ::: ~ < ~ ~ ~ ~ ~ ~ ~ ~ ~ 0 ~I~ ~ N N N ~ N N N N N ~ ~
!.--
1 1_ 2 2 3 2 2 1
2 1 4 3 1 1
5 1 6! II I! 4
1 4 1 1 1 2
2i 1]
.1. 2
:::
2 1 4 , 1.
",IS
21 3 1 2 1 3 1 2 17 4 2 4 i 3 2 15 1 2 2i 2 2, 9: 4 20 3
1
3 i..
31 J 3 2 2 4
1 1
! i! 5 6 3 5, 1:' 3 b B 2 7 7 6 1 ;i ~ ~ ~ 4 i- ~
711:: J 6 3 4 2 l' 1
I 1 1-
[, 8 E 76-) 4 7 3 2 - 1 2 1-,1_
2 1
__ 2.LZ 10 4 60 22 20
3 4 I ~ 3 7 6 5 2,
1 4 1 1
B Ie 1 25618143 1?.5Zl59 34°142222"
2 -~ -~-;1 ;, i-i Ii 2! 4- -4 1- ~ j- ~~-'~I"'; 1 1 1 1
1
J
3 4
15 3 2 9 4 5
6 '10, 8 4 2. 5 14 l'
1 Iii' 11 5 2 2 3 2
1
31 ~ l 2 1 3
1 2 1 1 2!0 20 3
I.! : 1: 1 5
3 2 2 2
.. 3 1
.1
50 45 28 43 28 22 20 6 31122 16 14 11 9 15 5 5 8 4 1 1 1 1
1 1
51,
1 1 1 4 6 6.2 4 B 3 5 64
4 4 2 2 B 3 L125 4 10 14 8 1 1. 2 6 J 4 3
27 1 2 29 1 1 2 1
2
4.2 312: 2;
3 1 J Ill,
1
4 2 1
3; 6
2: 2: l' 2, ,8; 2
3 4. 2'll;11'
2 " 5 1 3 l'
l: 2:
2: , 11
l' I
i 2" 4 ; I." 50:26;
3 2' I 1 1 21 ! 1 13 - 1 I' 2" 2 2' 6 1 '---6 2' 2 1 -3 fli 3 "I 114!
. -- 1
2,: 2, 1; 3~. .1, 6: ~ I, 1/ !}i 3; ; '[
1 4 1 5.
1 1 6
5 2 1
'1
':
1 1
6.
2: 1 4 ' " 1 Ii 1
Ii' iI, 1. ,3 1 1
I I 1 "
11 1 . I, I,
2i Ii
Ii , 21 1
;1 !
Nur:nber E.ach Specie.
1 36 2 ,
31 17
123
6 19
2
" 3 1
65 210 80
359 12 ~
, ~
U 9 5 ~ -u
_~L_ 1
n U
1 M
3 II 27 9
ill
" 9 3
"7 U 4
I' )Ii
I-' tv I-'
Table 39. Continued.
"larthern "'",terthruBh (Sciuru!> nov'eboracensifl) ,ouis.iana W.a.terthruah ~s motJtcl11a) -K"ntucky \.Iarbler (GeothYlv~{ormosa) Common 'Iello""'throat (Geothvlypis trichaa) 'i(>llov-hreasted Chat (Ict p rla virens) Hooded '.J2rbler ("ilf;on~lna·) Al:!.erlcan Redstart ($etq;h.aga rutlcl1h.) Orchard Oriole (lcten.!8 !pur-ius) &iltimnre Oriole (~zalbula) Erovn-hf"aded Co .... bird (Molothru8 liter)
1---- ---- I' I ' 2 1 1. 1 __ 1..-_..1.-1 1 .-.- ...
; 1 1 1 2 1 1 1 '_ )-4-- 3 1 4 2 2 1 i t 4 ) 2 3 5 2 2 1 4 2 2 3 2' 2 1 3 2 2: ); 2, 1 2 2 2\ .
~~ __ ~_ ~ 2 4 10 28 9 1 1117 J 4" 1 2: 5 ), I 2, 1 ) , ~, :r----- ~14~ ~ __ . _11 J. 2; 2 1 2.1 12 43 1
4'
, 2 5 2 13 2 2 1 7 20 1 5 10 35 4 1 5 2 1 14 4, 2 BI 5, 1 1 ~ I'l' I 1 I 4
1
11- 1 4 : I, ! !
l~ 21 1! 1:
I
, 1 10
91 1
102 41 162
1 S
12 jr 2 1 1 lSi 4 1 9' 1 4 1 i 5':3 I 14, Ii
1
; -~ t • - I 2 ,4 1:21 '5: i4 1 110:- 1 -14'21 1,' ::11 r" l' 'zj 1 70 _3_~ __ l3111)1 24 32 2213121522112 ),4 22'322 2 21:1' J2: 102 R~se-bre.asted Grosbeak (Pheuc:thus ludov1cianua) : i 1 10: 5 1 3! 6 11 ) 20 4 618 5< 13\ 2 .10S
.!Lue GrosbeaJ.. (Guiraca caerule'!.) ~ ,--- 5 I " 1, 1 . I 7 Indigo Bunting (Paaserinar:.yo.nea) I 31231191583'96204331153281091275151 12912 I; lIt. 435 Pai",ed 'u",in. (P"B"i~ <idB) I - - 2 1 _ - : 2 1 2 2 1" - :, '1 ' ' " I 17
SV~. SP"::a:~~~:y=r".n.) _____ r:~- :-4~1~' 81 '8. :. :3, :'i 51, 181 ~':1;'\'; ~t.i 3J,,~ .. ; 42 146\40\ "\241"1 ~,J;l~9114;t;7r3~-'o ;. ,;" i '; 48;' 31\' 10141\14'1191 68 3 \ JL_
Scarlet Tanager (Plranga o11vacea)
~~~:r~.l~:~~rin~~iYC:%PnWri £.ardinalis)
Urds/lOOH2/D&y r==;==i 321,212 2i 1 1.44 3211115112121.9131511)11 1.6,.515Ij-~1 11.6!91.sl.9 .21.61.51.1 1 ,921
11 A4 2.07 ______ . __ . • • ___ •. ___ ~.,._ •. ____ • ____ •• _ •. _. __ • ..,..- _____ ' ._,..."...,.. ". ....... ___ -..o-....... ,~~ ........ ~ .. '§
Notes: Table gives daily numbers of each species~ total numbers of each species for 51-day period, daily numbers of all species combined, and daily densities for all species combined. The mean density of birds for the 51-day period was 2.12/100 M2. Total area observed: 4,OOOM2
Source: J. J. Hebrard, unpublished data.
115' _______ _
C
122
(Mustella vison), and Otter (Lutra canadensis). Little information is presently available on population densities of these mammals in Louisiana. Greg Linscombe (LWFC) has acquired detailed data on all furbearing species in coastal Louisiana, but the data have not yet been summarized. When available, these data will allow detailed analysis of population phenomena and geographic distribution. A discussion of individual species and groups of species follows.
Common Muskrat (Ondatra zibethicus). O'Neil (1949) reported details of the life history of this species; this information has been summarized and updated by Lowery (1974). A brief synopsis follows.
The Common muskrat is reproductively active throughout the year, though there are peaks in November and March and a low point in July and August. The female produces an average of about four young per litter with five to six litters produced per year. They may reach sexual maturity at an age of 6 to 8 weeks.
Muskrats build grass houses, apparently only in areas lacking suitable substrate for burrowing. Muskrats trapped in marshes and released in upland areas immediately lost the house-building trait, living in burrows instead (O'Neil 1949).
In marsh areas, each house contains as many as four nests, each n~8t usually containing a brood in some state of development. As broods develop they are driven out of the house after which they construct their o~m. By this process, muskrat "colonies" can be started by relatively few pairs.
Palmisano (1972b) conducted a survey to determine the distribution and abundance of muskrats in the various marsh types of coastal Louisiana. The census was conducted by airplane and a count ~vas made of the number of muskrat houses along transects through the marshes. ONeil (1949) used an estimate of five trappable muskrats per house, while Palmisano (1972b) gives an estimate of three. Populations in swamp forest areas were not included in this survey, as the animals in this habitat live in streamside burrows rather than easily visible houses constructed of marshgrass.
The survey results were divided into two subdivisions: southw·est and southeast. The
southeastern section includes Atchafalaya Bay and extends east to the mouth of the Mississippi River; it is the section of interest in this report since it includes Barataria Basin. Re~
suIts are in Table 40. The are generally to smaller areas
but more importantly are the only ones available at present, Greg Linscombe (personal communication, LWFC) has accumulated more detailed information covering several years, but these data are as yet not summarized.
Table 40, Density of muskrat houses in Barataria Basin.
Saline Marsh Brackish Marsh
(including intermediate marsh areas)
Fresh Marsh
No. Houses/ 100/acres
14.98 30.92
2.27
Total No. Houses
54~3l2 106,823
7,573
Source: A. Palmisano. 1972. The distribution and abundance of Muskrats ... in Louisiana coastal marshes. 26th Ann. Meeting S.E. Assoc. Game and Fish Comm.
Palmisano found the greatest density of muskrat houses in brackish marsh areas. It is here that the preferred food of the muskrat, Three-cornered grass, Scirpus olneyi, grows most abundantly.
Palmisano conducted five surveys over a roughly 2-year period (November 1969-December 1971). The figures presented in Table 40 represent means of these five surveys. Populations and distributions were relatively stable for the first four counts, but the count of December 1971 showed an abrupt decline in brackish marsh populations. This count followed two abnormally dry summers, and this may have been a reason for the decline.
124
According to O'Neil (1949) overpopulation and subsequent overexploitation of food resources are important factors in population fluctuations. He also notes that periods of severely reduced populations are sometimes followed in a few years by peak catches.
Comparative takes of fur animals in Louisiana for the 1971-72 season and the 1972-73 season are shown in Table 41. These data apply to the state as a whole, since data for Barataria Basin alone are not available at this time. However, the harvest values for muskrat (and nutria) are categorized for eastern and western Louisiana (Barataria Basin is in the eastern segment). From these figures it can be seen that the eastern portion of the coastal zone contributed only 30% of the total take in 1971-72, yet the eastern and western portions of the state had very similar yields in 1972-73. Of course, harvest figures for anyone area are strongly affected by intensity of trapping effort as well as muskrat abundance.
Nutria (Myocastor coypus). The nutria was first introduced to Louisiana in 1938. The population continued to increase from that time, and by 1945 the animal was found throughout all the Louisiana coastal marsh (Dozier 1951). Since that time the nutria has become an important furbearing mammal to the industry of the state (Harris 1956).
Lowery (1974) has summarized the life history of this species. Nutria reach sexual maturity at an age of four to eight months. Litters contain from one to nine young, the average being four and a half. The gestation period is about 130 days and the female goes into estrus within one or two days after giving birth. Nongravid females go into estrus every 24 to 26 days.
Evidence for competition between nutria and nrlll.c"kiats is though it is almost certain to exist in areas "lhere the two are sympatric (occur together) 0 There is an
habitat separation between the two species. however. that could serve to competitive effects to some degree. Muskrat populations are highest in brackish marsh while Nutria are more characteristic of freshwater situations.
r
Table 41. Harvest values for fur animals in Louisiana during the 1971-72 and 1972-73 seasons.
1971-72 Season Approximate Price No. Pelts to Traerer Value
"'Muskrat (Eas tern) 98,000 @ 2.00 196,000.00 kHuskrat (H...:stcrn) 2?R,c,11 @ 3.50 799,795.50 mnk 24,299 @ 4.00 97,196.00
*Nutria (Eastern) 500,000 @ 2.00 1,000,000.00 "'Nutria (Western) 786,622 @ 4.00 3,146,488.00
Raccoon (Coastal) 30,000 @ 2.00 60,000.00 Raccoon (Up land) 50,632 @ 3.50 177,212.00 Opossum 8,310 @ .50 1,,155.00 Otter 5,440 @ 38.00 206,720.00 Skunk 114 @ .50 57.00 Fox 476 @ 4.50 2,142.00 Bobcat 136 @ 6.00 816.00 Beaver 126 @ 6.00 756.00 Coyote 11 @ 5.00 55.00 Civet Cat (spot ted skunk) 3 @ 2.00 6.00
Total Pelts 1,732,682 $5,691,398.50
Nutria Meat 8,250,000 Ibs @ .0(\ 660,000.00 Muskrat Heat 200,000 1bs @ .08 16,000.00 Raccoon Meat 440,000 Ibs @ .20 88,000.00 Opossum Meat 80,000 1bs @ .20 _16 ,000.00
Total ~!eat 8,970,000 780,000.00 Total Pelts and Heat. . $6,471,398.50
1972-7~~
"'Muskrat (E3.s tern) 173,393 @ $3.50 606,875.50 Huskrat (Western) 173,394 @ 4.75 823,621.50 Mink 44,062 @ 6.00 264,372.00
*Nutria (Eastern) 611,623 @ 3.25 1,987,774.75 *Nutria (Western) 1,000,000 @ 4.75 4,750,000.00
Raccoon (Coastal) 49,274 @ 4.50 221,733.00 Raccoon (Upland) 100,000 @ 6.00 600,000.00 Opossum 17,065 @ 1.25 21,331. 25 Otter 7,668 @ 42.00 322,056.00 Skunk 405 @ 1.00 405.00 Fox 1,899 @ 10.00 18,990.00 Bobcat 481 @ 12.00 5,772.00 Beaver 956 @ 5.00 4,780.00 Coyote 112_ @ 10.00 1,120.00
Total Pelts 2,180,332 $ 9,628,831.00
Nutria Meat 10,000,000 Ibs @ .08 800,000.00 Muskrat Heat 300,000 1bs @ .08 24,000.00 Raccoon Heat 840,000 1bs @ .22 18/,,800.00 Opossum Heat 160,000 1bs @ .20 ~_3_2,OOO.00
Total Neat 11,300,000 $ 1,040,800.00 ;'otnl Fe lts nnd Neat $10.,669,631. 00
*Primarily coastal. Source: Louisiana Wildlife and Fisheries Commission! 1973.
Population estimates of Nutria come primarily from catch data from trappers within the state. Numbers of Nutria trapped in Louisiana during the 1971-72 season and the 1972-73 season are shown in Table 41, During both years, harvest was in the western section of
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". __________________________________ .. c
126
the state than in the eastern area containing Barataria Basin. However~ even though harvest values for the basin alone are not available, nutria are an important resource of the region. Palmisano (1972a) shows a trend of declining catch records in marshes of high salinity. Highest production occurs in the fresh marsh habitat. From these data maximum production of nutria has been found to come from the fresh marsh areas where 884 pelts per 1,000 acres were produced; maximum production in brackish marshes was 191 pelts per 1,000 acres (Palmisano 1972a). Kays (1956) found population density of nutria to be 3 per acre in the brackish marsh surrounding a freshwater lake in Rockefeller Wildlife Refuge in the southwestern coastal area of the state. Chabreck and Dupuie (1970) say a marsh will produce only a certain number of nutria, and this harvest is one nutria per acre or less.
Nutria feed on coarser types of vegetation than do muskrats (O'Neil 1949). Foods eaten throughout the year in order of preference were found by Kays (1956) to be as follows: Pickerelweed (Pontederia cordata), Bull-tongue (Sagittaria falcata), Cattail (Typha sp.), Arrowhead (Sagittaria graminia), Squarestem rush (Eleocharis quadrangulata), Maidencane (Panicum hemitomon), water hyacinth (Eichornia crassipes), Break rush (Rhynchospora sp,), and Hater hyssop monnieri).
Deer, Squirrel and Rabbit. Data were obtained on populations of white~tailed deer (Odocoileus virginianus), squirrel (Sciurus sp,), rabbit (Sylvilagus sp,) from R, Murry and J, Kidd of the Louisiana Wildlife and Fisheries Commission (personal communication), The potential carrying capacity of marsh and swamp areas in Barataria Basin and present population estimates of the mammals in these areas are shown in Table 42.
p
Table 42. Potential population estimates rabbit of the marsh and Basin.
and present , and
SVlamp area.s of Barataria
- Per A.cre .~ -Deer Squirrel Rabbit
Swamp 1/30 1/4 1/3 Fresh Marsh 1/140* absent 1/1 Brackish Marsh 1/1000* absent 1/6 Intermediate Marsh 1/1000* absent 1/3 Saline Marsh absent absent 1/10
*Present populations Source: R. Murry and J. Kidd, La. State Fish and
Game Comm., personal cOIllIllunication.
During field investigations in Barataria Basin in 1973-74 conducted by the Center for Wetland Resources for Louisiana Offshore Oil Port, Inc., observations of deer, squirrel, and rabbit followed usual trends. Spoil banks in all marsh types and in the swamp were heavily utilized by rabbit. Three deer were seen during aerial observations in fresh marsh area just south of the Intracoastal Waterway. Deer tracks were observed in the swamp area usually along spoil banks and flat semi-dry areas within the swamp. The only squirrels observed in agreement with Table 42 were in the swamp area.
Mink, Otter, and Raccoon. In his study in southwest Louisiana, Kays (1956) found that Mink (Mustela vison) prefer fresh water habitats and that high populations in brackish marshes occur simultaneously with peaks in muskrat populations, since muskrats are a prefered food item.
Recent mink harvest for the state are shown in Table 41. From catch records, Palmisano (1972a) found no significant difference in peak mink production among vegetation types. Mean maximum catch value ranged from 11.9 per 1,000 acres in intermediate marsh (between true brackish marsh and fresh marsh) to 14·.2 per 1, 000 acres in fresh marsh 19
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128
-- - ~~~~~~~~----~----~~
Two Otters (Lutra canadensis) were seen during the LOOP study, one in the salt marsh and one in the swamp area. As Arthur (1928) states, the Otter is a solitary animal and very shy. The sight of one in its native habitat is very rare.
The Raccoon (Procyon lotor), from the aerial observations made in the LOOP study, is found throughout the basin. Although more were seen in saline environments, Palmisano (1972a) shows raccoon yield to be considerably higher in freshwater areas. This was related to the higher prices paid for the pelts and not necessarily a reflection of population differences.
Other Mammals Table 43 presents a list of mammals likely
to be found in the various habitats of Barataria Basin (G. Lowery and S. Guthans, personal communication). Except for those species already discussed, none has received intensive study in this area.
Table 43. MaIm11als that may occur in the "ariolls environmental units of Barataria Basin.
*Virginia opossum (Didelphis virginiaI)~), S, F
**Southeastern myotis (~l.:? .. austrorip~r~~), S
**Eastern pipistrelle (Pipistrellus subflavus),
**Red bat (Lasiurus borealis), S
:kJ'..Seminole bat (Lasiurus ~~nolus),
**Hoary bat (Lasiurus cinere~) I S
**Northern yellO\"r bat (Lasiuru~ intermedius),
~dEvening bat (Nycticeiu~ humeralls), S
*Nine-banded armadillo (Dasypus novemclnctus), S, F
*St>lamp rabbit (Sylvilagus aquaticus), All
*Fox squirrel (Sciurus niger), S
**Harsh rice rat (Oryzomys palustris») $, F
,HFulvous harvest mouse (Reithrodontomy~ fulves~!:!§)
*}'thf"\1i te- footed mouse O~e~~_<?f!1~~~_c_~_~ leucopus)
**Cotton mouse (Perom.J:'scus ~pinus)
*)~Hispid cotton rat C~gmodon_ hispidus)
**EFlc;;rprn Hnnrl rRt (~--.?toma florid.~.~_~::)
*Huskrat (Ondatra zibelhicus) I All
-'Nut ria (Nyocas tor ~oypus), All
*Atlantic hottle-nosed dolphin (Tursiops truncatus), Offshore, Bay, Sa
* Raccoon (Procyon ls"~_~ ... ~_!), All
,l-;Hink (Hus tella ..:;isoo), All
*Otter (Lutra canadensis), All
*t1hite-tailed deer (Odocoileus virginianus), S, F, B
Notes: *Sighted during LOOP Report study. **Known to rccur (personal COffi
fI1unications) G. Low"rey) S. Gu thans . S=swamp; F=fresh marsh; B=brackish marsh; Sa=s alt marsh; T=impounded tank farm.
Source: LOOP Re.eort 1976.
it ratur Cited
Allen, R. D. and F. P. Mangels. 1940. Studies of the nesting behavior of the black-crowned night heron. Proe. Linn. Soc. N.Y. 50-51: 1-28.
Arthur, S. 1928. The fur animals of Louisiana. La. Dept. Cons. Bull. 18.
Bateman, H. 1965. Clapper rail (Ra11us longirostrus) studies on Grand Terre Island, Jefferson Parish, La. Master's thesis, Louisiana State University, Baton Rouge, La.
Bent 3 A. 1922. Life histories of North American petrels and pelicans and their allies. Dover Pub .• New York.
Bray, J. R. and J. T. Curtis, 1957. An ordination of the upland forest communities of southern Wisconsin. Ecol. Monogr. 27:325-349.
Carter, M. R., L. A. Burns, T. R. Cavinder, K. R. Dugger, P. L. Fore, D. B. Hicks, H. L. Reve11s, and T. W. Schmidt. 1973. Ecosystems analysis of the big cypress swamp and estuaries. U.S. EPA Region IV, Atlanta, Ga.
Chabreck, R. H. 1962. Daily activity of nutria in Louisiana. J. Mammalogy 43(3):337-344.
---, and H. Dupuie. 1970. Monthly variation in nutria pelt quality. Proc. 24th Ann. Conf. S.E. Assoc. Game and Fish Comm. 24: 169-175.
---. 1971. The foods and feeding habits of alligators from fresh and saline environ-ments in Louisiana. Proc. 25th Ann. Conf. S. E. Assoc. Game and Fish Comm. 25:117-124.
1972. Vegetation, water, and soil characteristics of the Louisiana coastal region. Louisiana State University Agr. Exp. Sta. Bull. No. 664.
Conant, R. 1975. A field guide to reptiles and amphibians of eastern and central North . America. Houghton Mifflin Co., Boston, Mass.
Conner, W. H. 1975. Productivity and composition of a freshwater swamp in Louisiana. Master's thesis, Louisiana State University, Baton Rouge, La.
Darling, F. F. 1952. Social behavior and survival. Auk 69; 183-19 L
Day, J. W. Jr., W. Smith, P. Wagner, and W. Stowe. 1973. Community structure and carbon budget of a salt marsh and shallow bay estuarine system in Louisiana. Louisiana State Univer-
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sity Center for Wetland Resources Publ. No. LSU-SG-72-04. Baton Rouge~ La.
_____ , T. Butler 3 R. Allen, J. G. Gosselink, and W. C. Stowe. 1976. Flora and community metabolism of aquatic systems within the Louisiana Wetland. App. VI.4, vol. 2 pt. 2 in J. G. Gosselink, R. R. Miller, M. Hood, and L. M. Bahr Jr. (eds.). Louisiana Offshore Oil Port: Environmental Baseline Study. LOOP, Inc., New Orleans, La.
Dozier, H. 1951. The present status and future of nutria in the southeastern states. Presented at the 5th Ann. Meeting, S. E. Assoc. Game and Fish Comm.
Gauthreaux, S. A. Jr. 1971. A radar and direct visual study of passerine migration in southern Louisiana. Auk 88(2):343-365.
Gosselink~ J. G., R. R. Miller, M. Hood, and L. M. Bahr Jr. (eds). 1976. Louisiana Offshore Oil Port Environmental Baseline Study. LOOP, Inc. New Orleans, La.
Gunter, G. 1942. A list of fishes of the mainland of North and Middle America recorded from both fresh water and sea water. Amer. MidI. Nat. 28:305-326.
Harris, V. 1956. The nutria as a wild fur animal in Louisiana. Trans. 21st N. Amer. Wildl. Conf., pp. 474-486.
Hayden, B. P. Storm Wave Climate at Cape Hatteras, N.C.: Recent Secular Variations. Science 190 (4218) :981-982.
Hebrard, J. 1971. The nightly initiation of passerine migration in spring: a direct visual study. Ibis 113: 8-18.
Jaworski, E. 1972. The blue crab fishery, Barataria estuary. Louisiana State University Center for Wetland Resources Publ. No. LSU-SG-72-0l. Baton Rouge, La.
Joanen. T. and L. McNease. 1972. Population dist.dbulluH of with reference to the coastal marshes, Symp, Amer. Alligator Council Lake Charles La.
Kays. C, E. 1956. An ecological study with emphasis on nutria (Myocastor coypus) in the vicinity of Price Lake, Rockefeller Refuge, Cameron Parish, La. Master's thesis, Louisiana State University. Baton Rouge, La.
f
Lilly, J.C. 1969. The mind of the dolphin: A nonhuman intelligence. Avon Books, New York.
LOOP Report. 1976. ~ee Gosse1ink et ai. 1976. Louisiana Wildlife and Fisheries Carom. (LWFC).
1961. Louisiana waterfowl Final Repult July 19 1961. A contribu~
• W~17R and tion of PittlJlan~Robertson W~29R, New Orleans, La.
Lowery, G. H. Jr. 1945. Trans~Gulf spring migra~ tion of birds and the coastal hiatus. Wilson Bull. 57:92~121 . . 1973. Check-list of the mammals of Louisi----ana. Louisiana State University Museum of Natural History. Baton Rouge 3 La.
1974. The marmnals of Louisiana and its adjacent waters. Louisiana State University Press. Baton Rouge, La.
1974. Louisiana birds. Louisiana State University Press. Baton Rouge 3 La.
MacArthur, R. H., J. W. MacArthur, and J. Preer. 1962. On bird species diversity. II. Prediction of bird census from habitat measurements. Amer. Nat. 96(888):167-174.
McIlhenny, E. A. 1934. Bird city. Christopher Publishing House, Boston, Mass.
O'Neil, T. 1949. The muskrat in the Louisiana coastal marshes. Publ. Fed. Aid Sec., Louisiana Wildlife and Fisheries Comm., New Orleans, La.
Oney, J. 1954. Clapper rail survey and investigation study: final report. Ga. Game and Fish Comm., Game Mgt Div., Fed. Aid Proj. W-R-9.
Palmisano, A. W. 1970. Plant community/soil relationships in Louisiana coastal marshes. Ph.D. diss. Louisiana State University, Baton Rouge, La.
1971. Ibises in Louisiana. Louisiana Wildlife and Fish. Comm. Tech. Rept. No. 71-1.
1972a. Habitat preference of waterfowl and fur animals in the northern Gulf coast marshes. Proc. Coastal Harsh and Estuary Mgt. Symp., Louisiana State University, Div. Continuing Education, Baton Rouge, La.
1972B. The distribution and abundance of ~-muskrats in relation to
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vegatative types in Louisiana coastal marshes. Proc. 26th Ann. Conf. S. E. Assoc. Game and Fish Comm.
Penfound, W. T. and E. S. Hathaway. 1938. Plant communities of the marshlands of southeastern Louisiana. Ecol. Honogr. 8:1-56.
Pettus, D. 1963. Salinity and subspeciation in Natrix sipedon. Copeia (3):499-504.
Sauer, J. 1967. Geographic reconnaissence of seashore vegetation along the Mexican Gulf Coast. Louisiana State University Coastal Studies Institute Tech Rept. No. 56.
Saul~ G. E. 1974. Icthyofaunal investigation of the Tickfaw River drainage basin. Master's thesis, Louisiana State University, Baton Rouge, La.
Schoener, T. W. and A. Schoener. 1971. Structural habitats of West Indian Anolis lizards. I. Lowland Jamaica. Breviora (368).
Stone, J. H. 1976. Environmental factors relating to Louisiana's menhaden harvest. Louisiana State University Center for Wetland Resources Publ. No. LSU-SG-T-76-004.
Teal, J. 1962. Energy flow in the salt marsh ecosystem of Georgia. Ecology 43(4) :614-624.
Tinkle, D. 1959. Observations of reptiles and amphibians in a Louisiana swamp. Amer. MidI. Nat. 62(1):189~206.
Thom~ B. G. 1967. M&lgrove ecology and deltaic geomorphology: Tabasco, Mex. J. Ecol. 55: 301~343.
Van Engel, W. A. 1958. The blue crab and its fishery in Chesapeake Bay. Pt. I. Reproduction. early development, growth, and migration. Comm. Fisheries Rev, 20(6):6-11.
Vermeer, K. 1969. Great blue heron colonies in Alberta. Can. Field Nat. 83(3):237-242.
Ze1ickman, E., and A. Golovkin. 1972. Compo~ sition, structure, and productivity of neritic communi ties neat the bit-d colonies of the northern shores of Zemlya. Mar. BioI. 17:265-274.
F
APpendix: Louisiana's Refuges, Wildlife Management Areas, and Game Preserves J. J. Hebrard and L. A, Shiflett
NOMENCLATURE About 688,195 acres in coastal Louisiana are
maintained or managed for wildlife and game species. Some 434,110 acres of this land are owned or leased by the State of Louisiana and are maintained or managed by the Louisiana vJildlife and Fishpri Pi'l
Commission (LWFC). There are approximately 227 924 acres of coastal habitat owned by the Federal governmen t and administered by the Department of the Interior as wildlife refuges, The National Audubon Society owns the 26, 161-acre Paul J. Rainey Wildlife Refuge and Game Preserve. Figure 1 shows these areas and their status. Of these Wisner and Salvador Wildlife Management Areas are located in Barataria Basin.
State-controlled wildlife areas are of two general types, Wildlife Management Areas and Refuges/ Game Preserves. The major distinction bet'oleen the two types is that hunting is allowed on Wildlife Management Areas while no hunting is allowed on Refuges and Game Preserves (Alan Ensminger, LWFC, personal communication).
Federal refuges in coastal Louisiana are of two general types: (1) Special purpose for colonial nongame birds, and (2) for migratory waterfowl. No large-scale management practices are employed on the first type except for occasional predator control (Gabrielson 1943). Extensive management practices are used on migratory waterfowl refuges. The Migratory Bird Treaty Act makes conservation of these birds a Federal obligation. The Migratory Waterfowl Hunting Stamp Act provides funds for development and maintenance of these areas.
MANAGEMENT PRACTICES For refuges or wildlife management areas in
the coastal marshes. management techniques involve either manipulation of water or manipulation of the marsh vegetation itself. Manipulation of water is accomplished by creating shallow water impoundments, placing water control structures (weirs) in drainage systems, using earthen plugs in drainage systems, and by using artificial potholes. Marsh vegetation is manipulated by burning, tilling, treatment with herbicides, or planting (Chabreck 1975) .
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WATER MANIPULATION Marsh Impoundments.--The primary goal of
impoundment construction is management for waterfowl (Chabreck 1960). Impoundments are either permanently flooded or alternately drained and flooded to allow germination of annual grasses and to make the seeds of these grasses accessible to ducks (Chabreck 1960). Impoundments may also be beneficial to alligators t crawfish~ and deer (Chabreck 1960, Perry et al. 1970).
Chabreck (1960, 1975) has discussed construction of impoundments and problems associated with maintenance of levees. Impoundments are usually constructed by digging canals and using spoil for levees, incorporating existing levees when possible. Soil characteris tics influence the frequency of maintenance, i.e., subsoils in southeastern Louisiana. are generally too fluid for levee construction. Allowances must be made for shrinkage of levees because of moisture loss, decay of organic matter, and subsidence caused by the weight of levee materials.
Chabreck et al. (1974) determined duck usage of brackish and fresh water impoundments within the brackish marsh zone over a 2-year period (Table 1). Densities within the impoundments were compared with two control areas in natural marsh. Duck densities were highest in freshwater impoundments. while brackish water impoundments supported numbers similar to nonimpounded control areas.
Weirs.--In areas where levee construction is not feasible, some control over water levels can be gained by placing low sill dams (weirs) at strategic points in marsh drainage systems. The crest of these dams is generally set 6 inches below the marsh surface. The immediate effect of such a structure is to prevent complete drainage of marshes at low tide and to reduce tidal fluctuations. Water salin-ity is not si affected by weirs (Chabreck 1967). except dry periods when salt water would norma enter the marshes. , turbi-dity differs only slightly between ponds and 19kes in natural marsh areas and those in areas affected by ~leirs .
Secondary effects of weir construction include an increase in the production of certain aquatic plants, notably widgeongrass (Ruppia maritina). Whether this increased production is related to
--
Table 1. Duck usage of management units on Rockefeller Refuge, 1970-72 (from Chabreck et a1. 1974)
Brackish waLei- Freshwater Control
--------------Ducks per acre------------------
Aug. 0,01 0.03 0 0 0 0 Sept. 7.03 0.91 0.34 0,06 0.08 0.03 Oct. a 0.01 0.75 0.01 0.45 0 Nov. 6.91 0.10 17,40 26.02 0.51 12.50 Dec. 1.27 l.03 4.08 9.20 0.16 2.60 Jan. 0.41 2.12 8.25 0.57 0.15 13.00 Feb. 0.22 0.35 8.45 4,82 0.04 0.65 March 0.41 0.20 15.03 6.86 1.00 0.19 April 0.04 0.01 3.03 1.19 0.02 l.08 May 0 0 0.44 0 0 0 June 0 0 0.35 0.01 0 0.03 July 0 0 1.50 0 0 0.24
Average 1. 36 0.40 4.97 4.06 0.20 2.53 1971-72 --------------Ducks per acre-----------------
Aug. 1.89 1. 70 0.08 0.15 0.01 0 Sept. 0.01 0.10 0 0 0 0 Oct. 0 0.01 0.03 0.05 0 0 Nov. 0.19 0.30 34.60 3.51 0.40 0.40 Dec. 4.24 1.10 0.87 0.46 0.01 0.25 Jan. 0 1.93 5.63 2.27 0.09 0.09 Feb. 0.23 3.72 1.85 2.39 0.06 0.25 March 1.14 1.45 0.93 2.52 0.04 0.04 April 0.01 0.05 0.38 0.44 0 0.02 May 0 0 0.20 a 0 0.02 June 0 0.01 0.25 0.01 0 0.01 July 0 0 0 0 0.02 0.01
Average 0.64 0.86 3.74 0.98 0.05 0.09
Source: R. H. Chabreck, R. K. Yancey, and L. McNease. 1974. Duck usage of management units in the Louisiana coastal marsh. Presented 28th Ann. Conf. SE Assoc. Game and Fish Comm., White Silver Springs, W. Va.
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slightly lowered turbidities or reduced tidal flushing or some combination of factors is not clear from published research (Chabreck and Hoffpauir 1962, Chabreck 1967).
Chabreck (1967) reported changes in marsh vegetation behind some 9-year-old weirs. He reported a noticeable decline in black rush (Juncus romerianus) and an increase in spikerush (Eleocharis sp.) in high, well-drained marsh affected by the weirs. No changes in marsh vegetation were noted in low marsh behind 9-year-old weirs.
Spiller andChabreck (1975) found duck and coot populations to be about 4 times higher in ponds behind weirs than in similar ponds not subject to control by weirs. Chabreck (1967) reports observations of greatly increased duck usage of such areas. This may be related to increased widgeongrass production, which provides food for some species.
De la Bretonne and Avault (1971) studied movement of brown and white shrimp over weirs. Weirs are apparently not significant barriers to shrimp movement though they often have the effect of concentrating shrimp populations. Herke (1971) reported that weirs may delay emigration of very small juvenile brown shrimp. He found a similar effect on white shrimp emigration. Brown shrimp abundance is apparently not adversely affected by an increase in aquatic greater weights in semiimpounded marsh in the Biloxi W.M,A., while white shrimp attained greater weights in semi-impounded marsh on Marsh Island,
Burleigh (1966) found a significant effect of weirs on the landward distribution of blue crabs. Larger crabs were concentrated immediately landward of weirs, while smaller crabs were concentrated .4 to ,2 km landvlard of wei rs,
Burleigh (1966) analyzed distribution and abundance data for several fish species in relation to weirs. in Table 2. FIsh for which statistica icant effects were seen were concentrated either landVIard or seaward of weirs (see Table 2), Some species shovled a t
to concentrate in the immediate vicinity of weirs though results were not statistically significant.
Herke (1971) discusses the results of a study concerning the effects of semi-impoundment on five species of fish, Spot showed a faster growth rate
-
and attained greater weight in semi-impounded areas. Atlantic croaker and menhaden showed delayed emigration to the Gulf, and menhaden, in addition, were scarce in areas with much ~quatic vegetation. The bay anchovy showed reduced numbers in areas vIi th abundant aquatic Herke also points out that these effects are only indirectly the result of weir construction, and that factors such as migration patterns, habitat affinities, and food distribution interact in determining ultimate effects.
Table 2, Fish distributions affected by weirs (Burleigh 1966)
*Spotted gar (Lepisosteus oculatus) behind weirs
Alligator gar (Lepisosteus spatula) behind weirs
Ladyfish (Elops saurus) seaward of weirs
Skipjack herring (Alosa chrysochloris) concentrated near weirs
Largescale menhaden (Brevoortia patronus) near weirs
*Sea catfish (Arius felis) seaward of weirs
Largemouth bass (Micropterus salmoides) behind wei rs
Bluegill (Lepomis macrochirus) behind weirs
*Redear sunfish (Lepomis microlophus) behind weirs
*Spotted sunfish (Lepomis punctatus) behind weirs
Spotted seatrout (Cynoscion nebulosus) concentrated near weirs
Black drum (Pogonias cromis) seaward of weirs
Red drum (Sciaenops ocellata) apparently concentrated near weirs
Sheepshead (Archosargus probatacephalus) seaward of weirs
*Pinfish (Lagodon rhomboides) behind wei rs
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Table 2. Continued.
Southern flounder (Paralichthyes lethostigma) concentrated near weirs)
*Statistically significant effect.
Source: J. G. Burleigh. 1966. The effects of wakefield weirs on the distribution of fishes in a Louisiana saltwater marsh. Master's thesis, Louisiana State University, Baton Rouge, La.
Spiller and Chabreck (1975) compared distribution and abundance of a variety of wildlife species in weired marsh areas and in similar, nonweired control areas. Nongame birds (wading birds, shorebirds, gulls, and terns) were randomly distributed between the two types of areas except during extremely low water when natural marsh ponds were drained. Muskrats (Ondatra zibethicus) were randomly distributed between semi-impounded and control areas, while Nutria (Myocastor coypus) showed very slightly higher populations in natural marsh. Swamp rabbits were randomly distributed except in a February-March survey when significantly more rabbit scats were seen in semi-impounded marsh. Distribution and abundance of marsh rice rats (Oryzomys J2alustris) were not significantly affected by weirs.
Earthen Plugs.--The use of earthen plugs in marsh drainage systems is similar to the use of weirs except that the crest of earthen dams is usually high above water level. This prevents tidal exchange and causes runoff to flood across the marsh proper. Chabreck (1967) reports that ponds behind such plugs often have higher salinity than control ponds. He also found that this type of damming affected
Ie un vegetation, He further states that the effectiveness of earthen is increased when they are used in conjunction with a water
device. Artificial Di tches and Potholes, ~~-The benefit
to wildlife of artificial ditches and potholes has not been well established (Chabreck 1967), although alligators (Alligator mississippiensis) and some furbearing species may be obviously benefited by
II1II
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artificial \vater bodies during periods of drought. Ditches improve access by boat to remote marsh areas and have long been used by rs,
MANIPULATION OF MARSH VEGETATION
Practices such as marsh burning, tilling, use of herbicides, and planting have as their ultimate goal the maintenance of marshes dominated by threecornered grass (Scirpus olneyi), a preferred food of muskrat, by elimination of competition from other species (cf. McNease and Glasgow 1970, Ross and Chabreck 1972).
Burning of the marsh has been widely applied in coastal Louisiana and when done at certain times of the year gives three-cornered grass a competitive advantage. It is also used to attract snow geese that feed in freshly burned areas. Burning alone, however, is largely ineffective in maintaining stands of three-cornered grass (Chabreck 1975) .
Chandler (1969) examined the use of burning and tilling as a means of controlling wiregrass (Spartina patens) and saltgrass (Distichlis spicata) in fresh and salt marshes in southwestern Louisiana. He found that tilling fresh marsh areas reduced wire grass and increased the annual grasses and sedges, but burned plots were more easily tilled. Tilling salt marsh reduced the amount of salt-grass and wiregrass but was not effective in increasing leafy tree-square (Scirpus robustus). This technique is probably too expensive for use over large areas (Chandler 1969).
Herbicides have been used to control vegetation in marsh areas, but as yet they have not been useful in selective control (Chabreck 1975, Chandler 1969) •
Ross and Chabreck (1972) studied survival of artificially planted stands of three-cornered grass (Scirpus olneyi). They found that tilling before planting gave best survival and that burning before planting, though not as effective as tilling, gave much better survival than in stands planted with no site preparation. Planting was most successful in brackish marshes. in 2 to 4 inches of \Plater and at salinities ranging from 10 to 15 ppt.
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Planting time was also found to influence survival, December and January plantings showing 100 percent survival. Plots planted in July showed only 47.5 percent survival.
WISNER WILDLIFE MANAGEMENT AREA
Wisner Wildlife Management Area is located in southern Lafourche Parish and encompasses 22,153 acres of coastal marsh, including about 5 miles of shoreline on t he Gulf of Mexico. The predominant habitat type is saline marsh that occupies 11,576 acres. There are 2,485 acres of brackish marsh habitat and 90 acres of high ground. There are 6,345 acres of water 1n the saline marsh habitat and 1,658 acres of water in brackish marsh. This area is leased by the state and was originally 30,000 acres in total area. Approximately 3,700 acres in the southernmost part of the refuge were relegated to construction of a deep water port facility (Bob Beter, LWFC, personal communication).
The only management technique employed in the Wisner area has been the installation of weirs to create semi-impounded marsh. Construction of weirs began in 1959. At present,lO,388 acres of marsh are semi-impounded.
SALVADOR WILDLIFE MANAGEMENT AREA
Salvador Wildlife Management Area, located in southern St. Charles Parish, includes 30,604 acres of fresh marsh and swamp forest. It includes some shoreline in the northern portion of Lake Salvador as well as some along Bayou Couba and Lake Cataouatche.
This tract was purchased by the state in 1968 and was opened to the public for hunting and fishing
the 1968~1969 season. Access to the area is by boat only. All tely owned camps and cattle have been removed and overnight camping is prohibited. The area is extensively trapped to control populations of furbearers. After an area is trapped it is wet-burned to remove the dense vegetation and allow regrowth. This occurs from November until February. At the close of the
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trapping season the trapping ditches are dammed off to control "later flo",. The ditches are reopened at the beginning of the trapping season. Water hya~ cinth is sprayed with herbicide before the of wa terfow 1 seas on 0
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93°
State Wildlife Management Areas
1. Biloxi W.M.A. 2. Bohemia W.M.A. 3. Manchac W.M.A. 4. Pearl River W.M.A. 5. Point au Chieu W.M.A. 6. Sabine Island W.M.A. 7. Salvador W.M.A. 8. Wisner W.M.A. 9. Bonnet Carre Public Shooting Area
10. Pass a Loutre Game and Fish Preserve Hun ting Grounds
State Refuges
11. Louisiana State Wildlife Refuge and Game Preserve
12. Rockefeller \-lildlife Refuge and Game Preserve
13. Russell Sage (Marsh Island) IHldlife Refuge and Game Preserve
Ill. St. Tammany vJildlife Refuge
16. Delta Lacassine
18. Sabine 19. Shell Keys
Audubon Society
20. Paul J. Rainey Wildlife Refuge and Game Preserve
92°
Acres
39,583 33,000 5,261
26,716 28,404 8,103
30,604 :U,lS3
3,789 _66,000
255,510
13,000
86,000
78,000 1,600
178,600
142,845 ___ 8
227,924
26,161
91°
Hectares
16,019 13,355
2,129 10,811 11,495
3,279 12,385
8,965 1,533
26,710
103,402
5,261
34,803
72,278
824 ,748
12,855 47,808 ___ 3
92,239
10,587
90° 89°
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it ratur it
Burleigh, J. G. 1966. The effects of wakefield weirs on the distribution of fishes in a Louisiana saltwater marsh. Master's thesis, Louisiana State University. Baton Rouge, La.
Chabreck, R. H, 1960, Coastal marsh d~ ment8 for ducks in Louisiana. Proc. lI:th Ann. Conf., S,E. Assoc. Game and Fish Comm, October 23-26, Biloxi, Miss.
1967. Weirs, plugs and artificial pot~ holes for the management of wildlife in coas tal marshes. Presented at Marsh and Estuary Management Symp. Louisiana State University, Baton Rouge, La. July, 1967.
1975. Management of wetlands for wildlife habitat improvement. Presented at 3rd Biennial Conf., Estuarine Research Federation, Galveston, Tex October 6~9, 1975,
and C. M. Hoffpauir. 1962. The use of weirs in coastal marsh management in Louisiana. Presented at 16th Ann. Conf., S.E. Assoc. Game and Fish Carom., Charleston, S.C., October, 1962.
_____ , R. K. Yancey, and L. McNease. 1974. Duck usage of management units in the Louisiana coastal marsh. Presented at 28th Ann. Conf., S.E. Assoc. Game and Fish Comm., White Silver, Springs, W. Va., November 1974.
Chandler, G. A., Jr. 1969. Short term effects of various control measures on undesirable vegetation in a salt and fresh marsh. Master's thesis, Louisiana State University, Baton Rouge, La.
De La Bretonne, L. Jr. and J. W. Avault Jr. 1971. Movements of Brown Shrimp, Penaeus aztecus, and White Shrimp, Penaeus setiferus, over weirs in marshes of south Louisiana. Pages 651-654 in Proc. 25th Conf. S.E. Assoc. Game and Fish Comm., Charleston, S.C., 17-20 October 1971.
Gabrielson, I. N. 1943. Wildlife Refuges. MacMillan, New York.
Herke, W. H. 1971. Use of natural and semiimpounded Louisiana tidal marshes as nurseries for fish and crustaceans. Ph.D. diss., Louisiana State University, Baton Rouge, La.
McNease, L. L. and L. L. Glasgow. 1970. Experimental treatments for the control of wiregrass and saltmarsh grass in a brackish marsh, Proc, 24th Ann. ConL S.E. Assoc. Game and Fish Comm.
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Perry~ W. G. Jr., T. Jeanen, and L. McNease. 1970. Crawfish-waterfowl, a multiple use concept for impounded marshes. Pages 506-519 in Proc. 24th Ann. Conf. S.E. Assoc. Game and Fish Comm.
Ross, W. M. and R. H. Chabreck. 1972. Factors affecting the growth and survival of natural and planted stands of Scirpus olneyi. Presented at 26th Ann. Conf. Assoc. Game and Fish Comm., Knoxville, Tenn. October 1972.
Spiller, S. F. and R. H. Chabreck. 1975. Wildlife populations in coastal marshes influenced by weirs. Presented at 29th Ann. Conf., S.E. Assoc. Game and Fish Comm., St. Louis, Mo., October 1975.
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